eoe sub articles

EoE Sub Articles

<figure class='table'><table class='ck-table-resized' style='border-collapse:collapse;font-family:Calibri;font-size:11pt;table-layout:fixed;' cellspacing='0' cellpadding='0' dir='ltr' border='1' data-sheets-root='1' data-sheets-baot='1'><colgroup><col style='width:25%;' width='243'><col style='width:25%;' width='181'><col style='width:25%;' width='205'><col style='width:25%;' width='394'></colgroup><tbody><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>100 mm Achromatic Lens</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>THORLABS</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>AC254-100-B</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Broadband, 650 - 1,050 nm, achromatic lens focal length, 100 mm</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>20 MHz bandpass filter</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Minicircuits</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>BBP-21.4+</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Lumped LC Band Pass Filter, 19.2 - 23.6 MHz, 50 &#937;</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>200 mm Achromatic Lens</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>THORLABS</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>AC254-200-B</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Broadband, 650 - 1,050 nm, achromatic lens focal length, 200 mm</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Achromatic Half Waveplate</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Union Optic</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>WPA2210-650-1100-M25.4</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Broadband half waveplate</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Achromatic Quarter Waveplate</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Union Optic</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>WPA4210-650-1100-M25.4</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Broadband quarter waveplate</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Beam Sampler</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>THORLABS</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>BSN11</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>10:90 Plate Beamsplitter</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Dichroic Mirror</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>THORLABS</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>DMSP1000</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Other dichroics with a center wavelength around 1,000 nm can be used.</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>DMSO (Dimethyl sulfoxide)</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Sigma Aldrich</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>472301</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Solvent for calibration of Raman shift. Other solvents with known Raman peaks can be used.</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Electrooptic Amplitude Modulator</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>THORLABS</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>EO-AM-NR-C1</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Two EOMs are needed for orthogonal modulation and dual-channel imaging. Resonant version is recommended so lower driving voltage can be used.</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>False H&amp;E Staining Script</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Matlab</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>https://github.com/TheFuGroup/HE_Staining</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Fanout Buffer</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>PRL-414B</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Pulse Research Lab</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>1:4 TTL/CMOS Fanout Buffer and Line Driver, for generating the EOM driving frequency and the reference to the lock-in</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Fast Photodiode</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>THORLABS</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>DET10A2</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Si Detector, 1 ns Rise Time</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Frequency Divider</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>PRL-220A</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Pulse Research Lab</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>TTL Freq. Divider (f/2, f/4, f/8, f/16), for generating 20MHz from the laser output.</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Highly Dispersive Glass Rods</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Union Optic</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>CYLROD01</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>High dispersion H-ZF52A Rod lens 120 mm, SF11 Rod lens 100 mm</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Insight DS+</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Newport</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Laser system capable of outputting two synchronzied pulsed lasers (one fixed beam at 1, 040 nm and one tunable beam, ranging from 680-1,300 nm) with a repetition rate of 80 MHz.&#160;</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Lock-in Amplifier</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Liquid Instruments</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Moku Lab</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Lock-in amplifier to extract SRS signal from the photodiode. A Zurich Instrument HF2LI or similar instrument can be used as well.</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Mirrors</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>THORLABS</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>BB05-E03-10</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Broadband Dielectric Mirror, 750 - 1,100 nm. Silver mirrors can also be used.</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Motorized Delay Stage</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Zaber</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>X-DMQ12P-DE52</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Delay stage for fine control of the temporal overlap of the pump and the Stokes lasers. Any other motorized stage should work.</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Oil Immersion Condensor</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Nikon</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>CSC1003</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>1.4 NA. Other condensers with NA&gt;1.2 can be used.</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Oscilloscope</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Tektronix</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>TDS7054</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Any other oscilloscope with 400 MHz bandwdith or higher should work.</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Phase Shifter</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>SigaTek</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>SF50A2</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>For shifting the phase of the modulation frequency</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Photodiode</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Hamamatsu Corp</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>S3994-01</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Silicon PIN diode with large area (10 x 10 cm2). Other diodes with large area and low capacitance can be used.</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Polarizing Beam Splitter</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Union Optic</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>PBS9025-620-1000</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Broadband polarizing beamsplitter</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Refactive Index Database</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>refractiveindex.info</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Retro-reflector</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Edmund Optics</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>34-408</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>BBAR Right Angle Prism. Other prisms or retroreflector can be used.</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>RF Power Amplifier</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Minicircuits</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>ZHL-1-2W+</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Gain Block, 5 - 500 MHz, 50 &#937;</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Scan Mirrors</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Cambridge Technologies</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>6215H</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>We used a 5mm mirror set with silver coating</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>ScanImage</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Vidrio</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>ScanImage Basic</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Laser scanning microscope control software</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Shortpass Filter</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>THORLABS</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>FESH1000</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>25.0 mm Premium Shortpass Filter, Cut-Off Wavelength: 1,000 nm. For efficient suppression of the Stokes, two filters may be necessary.</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Upright Microscope</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Nikon</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Eclipse FN1</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Any other microscope frame can be used. If a laser scanning microscope is available, it can be used directly. Otherwise, a galvo scanner and scan lens needed to be added to the microscope.</td></tr><tr style='height:21px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Water Immersion Objective</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Olympus</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>XLPLN25XWMP2</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>The multiphoton 25X Objective has a NA of 1.05. Other similar objectives can be used.</td></tr></tbody></table></figure>

two-color stimulated raman scattering imaging of mouse brain tissue

<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:2904/1257;' src='https://cloudfront.jove.com/files/ftp_upload/23443/23443_Figure_1_editor_23443.jpg' alt='23443_Figure_1.jpg' /></figure>Figure 1: Schematic of one-color SRS imaging setup.&#160;Construction of a spectral-focusing SRS microscope in transmission mode. X and Y represent the orthogonal outputs. Abbreviations: SRS = stimulated Raman scattering; DL = retroreflector-based delay line; Div = divider; FB = fanout buffer; AT = attenuator; PS = phase shifter; PA = power amplifier; DCM = dichroic mirror; GM = galvo mirrors; EOM = electrooptic modulator; POM = pick-off mirror; PBS = polarizing beam splitter, BRC = birefringent crystal; QWP = quarter-wave plate; HWP: half-wave plate; PD = photodiode; GR = glass rod; BB = Beam Block; SPF = shortpass filter; CL = collimating lens; BS = beam size changing lens.&#160;<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:3000/2818;' src='https://cloudfront.jove.com/files/ftp_upload/23443/23443_Figure_2_editor_23443.jpg' alt='23443_Figure_2.jpg' /></figure>Figure 2: Representative temporal overlap.&#160;(A) The pump and Stokes beams are seen to be temporally overlapped on the oscilloscope. Oscilloscope cursors are used to mark the temporal positions of the pump and Stokes beams. This overlap is satisfactory as a starting point to further tweak temporal overlap with a delay stage. (B) Satisfactory representative modulation depth of one EOM at 20 MHz. (C) Satisfactory pulse modulation while two EOMs are in use. (D) Satisfactory pulse train modulation after birefringent quartz crystal and half-wave plate installation on the doubly modulated Stokes arm. Abbreviation: EOM = electrooptic modulator.<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:2328/2584;' src='https://cloudfront.jove.com/files/ftp_upload/23443/23443_Figure_3_editor_23443.jpg' alt='23443_Figure_3.jpg' /></figure>Figure 3: Representative SRS and pump signals.&#160;(A) Misaligned pump signal detected in DC channel. (B) Misaligned SRS signal detected by photodiode.&#160;(C) Satisfactory, centered pump signal in the DC channel. (D) Satisfactory SRS signal centered on the AC channel. Abbreviation: SRS = stimulated Raman scattering. &#160;<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:2014/1176;' src='https://cloudfront.jove.com/files/ftp_upload/23443/23443_Figure_4_editor_23443.jpg' alt='23443_Figure_4.jpg' /></figure>Figure 4: Spectral resolution characterization.&#160;A gaussian function was fit to the 2,913 cm-1&#160;Raman DMSO peak. The FWHM calculated gave a resolution of 15 cm-1&#160;for the system. Abbreviations: DMSO = dimethyl sulfoxide; FWHM = Full Width at Half Maximum.<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:2919/1224;' src='https://cloudfront.jove.com/files/ftp_upload/23443/23443_Figure_5_editor_23443.jpg' alt='23443_Figure_5.jpg' /></figure>Figure 5: Schematic of two-color SRS imaging setup.&#160;Construction of a two-color SRS microscope in the transmission mode. X and Y represent the orthogonal outputs. Abbreviations: DL = retroreflector based delay line; Div = divider; FB = fanout buffer; AT = attenuator; PS = phase shifter; PA = power amplifier; DCM = dichroic mirror; GM = galvo mirrors; EOM = electrooptic modulator; PBS = polarizing beam splitter; BRC = birefringent crystal; QWP = quarter-wave plate; HWP = half-wave plate; PD = photodiode; GR = glass rod; BB = Beam Block, SPF = shortpass filter; CL = collimating lens; POM = pick-off mirror; BS&#160;= beam size changing&#160;lens.&#160;<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:4408/1852;' src='https://cloudfront.jove.com/files/ftp_upload/23443/23443_Figure_6_editor_23443.jpg' alt='23443_Figure_6.jpg' /></figure>Figure 6: Schematic of two-color SRS imaging Epi-mode set-up.&#160;Construction of a two-color SRS microscope in the epi-mode. X and Y represent the orthogonal outputs. Abbreviations: DL = retroreflector based delay line; Div = divider; FB = fanout buffer; AT = attenuator; PS = phase shifter; PA = power amplifier; DCM = dichroic mirror; GM = galvo mirrors; EOM = electrooptic modulator; PBS = polarizing beam splitter; BRC = birefringent crystal; QWP = quarter-wave plate; HWP = half-wave plate; PD = photodiode; GR = glass rod; BB = Beam Block, BPF = bandpass filter; CL = collimating lens; POM = pick-off mirror; BS =&#160;beam size changing&#160;lens.

Two-Color Stimulated Raman Scattering Imaging of Mouse Brain Tissue

Source:&#160;Espinoza, R.,&#160;et al. Real-Time, Two-Color Stimulated Raman Scattering Imaging of Mouse Brain for Tissue Diagnosis.&#160;J. Vis. Exp. ...

Take a mouse brain slice inside a chamber on a slide and place it under a microscope with a stimulated Raman scattering, or SRS, imaging system. Focus two synchronized laser beams, known as the pump and Stokes beams, onto the tissue. The energy difference between these beams matches the vibrational frequency of specific molecules, inducing molecular vibrations. Excite the tissue lipids and proteins, having unique molecular vibrations, using distinct frequency pairs of the synchronized beams. The excitation facilitates energy transfer between the beams, reducing the pump beam intensity while increasing the Stokes beam intensity. The relative intensity change is detected as an SRS signal that helps identify the molecules. A photodetector collects the combined SRS signals from the sample.&#160; Assign the lipid and protein signals separate colors, creating a two-colored image, to identify the proteins and lipids in the brain tissue.

two-color-stimulated-raman-scattering-imaging-of-mouse-brain-tissue

Universidad de Cartagena UDEC

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuroimaging

Synaptic & Cellular Imaging

29 Views.  Source: Espinoza, R., et al. Real-Time, Two-Color Stimulated Raman Scattering Imaging of Mouse Brain for Tissue Diagnosis. J. Vis. Exp. (2022).  The video demonstrates two-color stimulated Raman scattering (SRS) imaging of mouse brain tissue sections. Two synchronized laser beams are directed onto the tissue section to excite molecular vibrations, resulting in a relative intensity change in the beams. Lipids and proteins in the tissue are detected using distinct frequency pa...

Video: Two-Color Stimulated Raman Scattering Imaging of Mouse Brain Tissue - Concept

Multiplex Chemical Imaging Based on Broadband Stimulated Raman Scattering Microscopy

Stimulated Raman scattering (SRS) microscopy is a nonlinear optical technique for label-free chemical imaging. This analytical tool delivers chemical maps at high speed, and high spatial resolution of thin samples by directly interrogating their molecular vibrations. In its standard implementation, SRS microscopy is narrowband and forms images with only a single vibrational frequency at a time. However, this approach not only hinders the chemical specificity of SRS but also neglects the wealth of information encoded within vibrational spectra. 
These limitations can be overcome by broadband SRS, an implementation capable of extracting a vibrational spectrum per pixel of the image in parallel. This delivers hyperspectral data that, when coupled with chemometric analysis, maximizes the amount of information retrieved from the specimen. Thus, broadband SRS improves the chemical specificity of the system, allowing the quantitative determination of the concentration of the different constituents of a sample. Here, we report a protocol for chemical imaging with broadband SRS microscopy, based on a home-built SRS microscope operating with a custom differential multichannel-lock-in amplifier detection. It discusses the sample preparation, alignment of the SRS apparatus, and chemometric analysis. By acquiring vibrational Raman spectra, the protocol illustrates how to identify different chemical species within a mixture, determining their relative concentrations.

We present a protocol to acquire chemical images with broadband stimulated Raman scattering (SRS) microscopy. Based on an SRS microscope that operates with differential multichannel-lock-in detection, the protocol describes the sample preparation, adjustment of the SRS apparatus, and chemometrics to disentangle different constituents of chemically heterogeneous samples.

Stimulated Raman scattering (SRS) microscopy is a nonlinear optical technique for label-free chemical imaging. This analytical tool delivers chemical maps ...

JoVE Journal

Engineering

Direct Comparison of Hyperspectral Stimulated Raman Scattering and Coherent Anti-Stokes Raman Scattering Microscopy for Chemical Imaging

Stimulated Raman scattering (SRS) and coherent anti-Stokes Raman scattering (CARS) microscopy are the most widely used coherent Raman scattering imaging technologies. Hyperspectral SRS and CARS imaging offer Raman spectral information at every pixel, which enables better separation of different chemical compositions. Although both techniques require two excitation lasers, their signal detection schemes and spectral properties are quite different. The goal of this protocol is to perform both hyperspectral SRS and CARS imaging on a single platform and compare the two microscopy techniques for imaging different biological samples. The spectral focusing method is employed to acquire spectral information using femtosecond lasers. By using standard chemical samples, the sensitivity, spatial resolution, and spectral resolution of SRS and CARS in the same excitation conditions (i.e., power at the sample, pixel dwell time, objective lens, pulse energy) are compared. The imaging contrasts of CARS and SRS for biological samples are juxtaposed and compared. The direct comparison of CARS and SRS performances would allow for optimal selection of the modality for chemical imaging.

This paper directly compares the resolution, sensitivity, and imaging contrasts of stimulated Raman scattering (SRS) and coherent anti-Stokes Raman scattering (CARS) integrated into the same microscope platform. The results show that CARS has a better spatial resolution, SRS gives better contrasts and spectral resolution, and both methods have similar sensitivity.

Stimulated Raman scattering (SRS) and coherent anti-Stokes Raman scattering (CARS) microscopy are the most widely used coherent Raman scattering imaging ...

Chemistry

In vivo Imaging of Biological Tissues with Combined Two-Photon Fluorescence and Stimulated Raman Scattering Microscopy

Stimulated Raman scattering (SRS) microscopy enables label-free imaging of the biological tissues in its natural microenvironment based on intrinsic molecular vibration, thus providing a perfect tool for in vivo study of biological processes at subcellular resolution. By integrating two-photon excited fluorescence (TPEF) imaging into the SRS microscope, the dual-modal in vivo imaging of tissues can acquire critical biochemical and biophysical information from multiple perspectives which helps understand the dynamic processes involved in cellular metabolism, immune response and tissue remodeling, etc. In this video protocol, the setup of a TPEF-SRS microscope system as well as the in vivo imaging method of the animal spinal cord is introduced. The spinal cord, as part of the central nervous system, plays a critical role in the communication between the brain and peripheral nervous system. Myelin sheath, abundant in phospholipids, surrounds and insulates the axon to permit saltatory conduction of action potentials. In vivo imaging of myelin sheaths in the spinal cord is important to study the progression of neurodegenerative diseases and spinal cord injury. The protocol also describes animal preparation and in vivo TPEF-SRS imaging methods to acquire high-resolution biological images.

In vivo Imaging of Biological Tissues with Combined Two-Photon Fluorescence and Stimulated Raman Scattering Microscopy

Stimulated Raman scattering (SRS) microscopy allows label-free imaging of biomolecules based on their intrinsic vibration of specific chemical bonds. In this protocol, the instrumental setup of an integrated SRS and two-photon fluorescence microscope is described to visualize cellular structures in the spinal cord of live mice.

Stimulated Raman scattering (SRS) microscopy enables label-free imaging of the biological tissues in its natural microenvironment based on intrinsic ...

Two-Color Stimulated Raman Scattering Imaging of Mouse Brain Tissue

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Two-Color Stimulated Raman Scattering Imaging of Mouse Brain Tissue

Multiplex Chemical Imaging Based on Broadband Stimulated Raman Scattering Microscopy

Direct Comparison of Hyperspectral Stimulated Raman Scattering and Coherent Anti-Stokes Raman Scattering Microscopy for Chemical Imaging

In vivo Imaging of Biological Tissues with Combined Two-Photon Fluorescence and Stimulated Raman Scattering Microscopy