Highly-Multiplexed Tissue Imaging with Raman Dyes

Podsumowanie

Electronic pre-resonance stimulated Raman scattering (epr-SRS) imaging of rainbow-like Raman dyes is a new platform for highly multiplexed epitope-based protein imaging. Here, we present a practical guide including antibody preparation, tissue sample staining, SRS microscope assembly, and epr-SRS tissue imaging.

Streszczenie

Visualizing a vast scope of specific biomarkers in tissues plays a vital role in exploring the intricate organizations of complex biological systems. Hence, highly multiplexed imaging technologies have been increasingly appreciated. Here, we describe an emerging platform of highly-multiplexed vibrational imaging of specific proteins with comparable sensitivity to standard immunofluorescence via electronic pre-resonance stimulated Raman scattering (epr-SRS) imaging of rainbow-like Raman dyes. This method circumvents the limit of spectrally-resolvable channels in conventional immunofluorescence and provides a one-shot optical approach to interrogate multiple markers in tissues with subcellular resolution. It is generally compatible with standard tissue preparations, including paraformaldehyde-fixed tissues, frozen tissues, and formalin-fixed paraffin-embedded (FFPE) human tissues. We envisage this platform will provide a more comprehensive picture of protein interactions of biological specimens, particularly for thick intact tissues. This protocol provides the workflow from antibody preparation to tissue sample staining, to SRS microscope assembly, to epr-SRS tissue imaging.

Wprowadzenie

Complex tissue systems are composed of distinct cellular subpopulations whose spatial locations and interaction networks are deeply intertwined with their functions and dysfunctions^1,2. To reveal the tissue architecture and interrogate its complexity, knowledge of the spatial locations of proteins at single-cell resolution is essential. Hence, highly multiplexed protein-imaging technologies have been increasingly appreciated and could become a cornerstone for studying tissue biology^3,4,5. Current common multiplexed protein imaging methods can be classified into two main categories. One is serial immunofluorescence imaging relying on multiple rounds of tissue staining and imaging, and the other is imaging mass cytometry coupled with heavy metal tagged antibodies^{6,7,8,9,10,11,12}.

Here, an alternative strategy for multiplexed antibody-based protein imaging is introduced. Unlike the prevalent fluorescence imaging modality, which can only visualize 4-5 channels simultaneously due to the broad excitation and emission spectra (full width at half maximum (FWHM) ~500 cm^-1), Raman microscopy exhibits much narrower spectral linewidth (FWHM ~10 cm^-1) and hence provides scalable multiplexity. Recently, by harnessing the narrow spectrum, a novel scheme of Raman microscopy named electronic pre-resonance stimulated Raman scattering (epr-SRS) microscopy has been developed, providing a powerful strategy for multiplexed imaging¹³. By probing the electronically coupled vibrational modes of Raman dyes, epr-SRS achieves a drastic enhancement effect of 10¹³-fold on Raman cross-sections and overcomes the sensitivity bottleneck of conventional Raman microscopy (Figure 1A)^13,14,15. As a result, the detection limit of epr-SRS has been pushed to sub-µM, which enables Raman detection of interesting molecular markers such as specific proteins and organelles inside cells^13,16. In particular, utilizing Raman dye-conjugated antibodies, epr-SRS imaging of specific proteins in cells and tissues (called immuno-eprSRS) was demonstrated with comparable sensitivity to standard immunofluorescence (Figure 1B)^13,17. By tuning the pump wavelength by only 2 nm, the epr-SRS signal will be completely off (Figure 1B), which showcases high vibrational contrast.

On the probe side, a set of rainbow-like Raman probes called Manhattan Raman scattering (MARS) dyes has been developed for antibody conjugation^13,18,19,20. This unique Raman palette consists of novel dyes bearing π-conjugated triple bonds (Supplementary Material), each displaying a single and narrow epr-SRS peak in the bioorthogonal Raman spectral range (Figure 1C). By modifying the structure of the core chromophore and isotopically editing both atoms of the triple bond (Supplementary Material), spectrally separated Raman probes have been developed. Leveraging the scalable multiplexity, epr-SRS microscopy coupled with the MARS dye palette offers an optical strategy for one-shot multiplex protein imaging in cells and tissues.

Immuno-eprSRS provides an alternative strategy to current multiplex protein imaging methods with unique strengths. Compared to fluorescence approaches with cyclic staining, imaging, and signal removal, this Raman-based platform ensures single-round staining and imaging. Therefore, it circumvents practical complexity in cyclic procedures and largely simplifies the protocol, hence opening new territories of multiplexed protein imaging. For instance, harnessing a Raman-dye-tailored tissue clearing protocol, immuno-eprSRS has been extended to three dimensions for highly multiplexed protein mapping in thick intact tissues¹⁷. Over 10 protein targets were visualized along millimeter-thick mouse brain tissues¹⁷. More recently, coupling immuno-eprSRS with an optimized biomolecule-retention expansion microscopy (ExM) protocol²¹, one-shot nanoscale imaging of multiple targets has also been demonstrated²². Compared to imaging mass spectroscopy^4,9, epr-SRS is nondestructive and has intrinsically optical sectioning ability. Furthermore, epr-SRS is more time-efficient on tissue scanning. Typically, a tissue region of 0.25 mm² with a pixel size of 0.5 µm takes merely a few minutes to image for a single epr-SRS channel. For example, the total imaging time of four SRS channels plus four fluorescence channels in Figure 4 is about 10 min.

Protokół

The protocol was conducted in accordance with the animal experimental protocol (AC-AABD1552) approved by the Institutional Animal Care and Use Committee at Columbia University.

1. Preparation of Raman-dye-conjugated antibodies

1. Prepare the conjugation buffer as ~0.1 M NaHCO₃ in PBS buffer, pH = 8.3, store at 4 °C.
2. Prepare N-hydroxysuccinimidy (NHS) ester-functionated MARS probe (Supplementary Material) solution as 3 mM in anhydrous DMSO. Synthesis of MARS probes can be referred to prior reports^13,17,18.
   NOTE: For storage purposes, the dye NHS ester solution must be protected from light and kept at -20 °C.
3. Dissolve antibody solids in the conjugation buffer to a concentration of 2 mg/mL. For antibodies that are dissolved in other buffers, exchange them into the conjugation buffer to a concentration of 1-2 mg/mL with centrifugal filters.
   NOTE: Highly cross-adsorbed secondary antibodies are preferred for multiplex staining to minimize cross-species reactivity. The secondary antibodies used are listed in Table 1 and Table of Materials.
4. Perform the conjugation reaction.
   1. For secondary antibodies, add 15-fold molar excess of dye solution to the antibody solution in a glass vial slowly with stirring. For example, in 0.5 mL 2 mg/mL antibody solution, add 35 µL 3 mM dye solution.
   2. Incubate the reaction mixture at room temperature (RT) with stirring for 1 h. Protect the reaction from light.
5. Purification.
   1. Prepare the slurry of gel filtration resin (Table of Materials) in PBS buffer, following steps 1.5.2-1.5.4.
   2. Add 10 mL of gel filtration resin powder into 40 mL of PBS buffer inside a 50-mL tube.
   3. Keep the solution in a 90 °C water bath for 1 h.
   4. Decant the supernatant and re-add PBS to 40 mL. Store the slurry at 4 °C.
   5. Pack the size exclusion column (1-cm diameter, gravity-flow columns) with the slurry solution to the height of 10-15 cm.
   6. Rinse and wash the column with ~10 mL of PBS buffer to further pack the resin.
   7. Pipet the conjugation reaction mixture (~0.5 mL) to the column. Immediately add 1 mL of PBS buffer as the elution buffer when all reaction mixture is loaded. Constantly refill the elution buffer (PBS) to the column.
   8. Collect the eluate of the conjugate solution by looking at the color on the column (MARS dyes have light green to blue colors) or measuring the absorbance at 280 nm (A280).
6. Concentrate the collected solution to 1-2 mg/mL with a centrifugal filter.
7. Determine the concentration and the average degree of labeling (DOL, dye-to-protein ratio) by measuring the ultraviolet-visible (UV-Vis) spectrum of the conjugate solution with a Nano plate reader.
   ​NOTE: Supplementary Material provides properties of MARS-dye NHS-esters for calculation. The normal DOL for the secondary antibody is around 3.

2. Tissue sample preparation

1. Paraformaldehyde fixed mouse brain tissues.
   1. Anesthetize the mice (C57BL/6J, Female, 25 d postnatal) with isoflurane. Assess the proper anesthetization with a toe pinch test.
   2. Kill the mice by cervical displacement. Perfuse the mice immediately with 4% paraformaldehyde (PFA) in PBS transcardially.
   3. Collect the mouse brain, following steps 2.1.4-2.1.5
   4. Cut upward from the brain stem along the sagittal suture. Peel the two halves of the skull away to the side and scoop out the brain with a tweezer.
   5. Fix the collected brain in 4% PFA in PBS at 4 °C for 24 h. Then, wash the brain in PBS buffer at 4 °C for 24 h to remove excess PFA.
   6. Place solid agarose into water to a final concentration of 7% (w/v) in a beaker, with a loose lid. Stir the solution with a glass stirring rod. Heat the slurry in microwave until the solution is clear.
   7. Allow the agarose to cool to 45-55 °C.
   8. Pour the liquid agarose into a small chamber, then transfer the brain from PBS to liquid agarose and orient it with a spatula to embed the brain. Wait for the tissue-agarose block to harden.
   9. Section the tissue-agrose into 40-µm-thick coronal slices using a vibratome.
   10. Transfer the tissue to a 4-well plate for the following staining. Remove the agarose with a tweezer. Wash the tissue with 1 mL of PBS, three times.
2. Fixed frozen mouse pancreas tissues.
   1. Fix the mouse pancreata in 4% PFA in PBS at 4 °C with rocking for 16-20 h.
   2. Wash the sample in 1 mL of PBS (4 °C) three times to remove PFA.
   3. Embed the sample (~0.3-0.5 cm in size) in optimal cutting temperature (OCT) compound blocks. Put 2 drops of OCT into a plastic cryomold. Place the tissue in correct orientation and pour OCT on top of tissues until none of the tissue remains exposed.
   4. Section the pancreata to 8-µm-thick slices and immobilize them onto a tissue binding glass slide, store them in -80 °C.
   5. Before staining, equilibrate the specimen to RT. Wash the tissue with PBS to remove OCT blocks.
3. FFPE samples.
   1. Bake the FFPE tissue slide at 60 °C for 10 min.
   2. Deparaffinization and rehydration: Place samples sequentially in the following solutions in a 50-mL tube at RT for 3 min each time with mild shaking:
      xylene two times,
      ethanol two times,
      95% (vol/vol) ethanol in deionized water two times,
      70% (vol/vol) ethanol in deionized water two times,
      50% (vol/vol) ethanol in deionized water one time,
      deionized water one time.
   3. Transfer the sample into 20 mM sodium citrate (pH 8.0) at 100 °C in a glass jar. Make sure the tissues are immersed in the solution.
   4. Put the jar in a 60 °C water bath for 45 min.
   5. Wash the sample with deionized water at RT for 5 min.

3. Tissue immuno-eprSRS staining

1. Use a hydrophobic pen to draw a boundary around the tissue sections on the slide.
   NOTE: A slide staining jar is used for following incubation steps of tissue on the slide. Floating tissues (40-µm-thick mouse brain sections) are stained in well plates.
2. Incubate the tissues with 0.3-0.5% PBST (Triton X-100 in PBS) for 10 min.
3. Incubate the tissues with blocking buffer (5% donkey serum, 0.5% Triton X-100 in PBS) for 30 min.
4. Prepare the primary staining solution: add all primary antibodies to 200-500 µL of staining buffer (2% donkey serum, 0.5% Triton X-100 in PBS) at desired concentrations. Centrifuge the primary staining solution at 13,000 x g for 5 min. Only use the supernatant if precipitates form.
5. Incubate the tissue in the primary antibody solution at 4 °C for 1-2 days.
   NOTE: For staining tissue sections on the slide, put the sample in a staining box with a wet wipe to maintain humidity.
6. Wash the slides three times with 0.3-0.5% PBST at RT for 5 min each. Use 1 mL PBST for floating tissues. For tissues on the slide, wash the slides in a slide staining jar and make sure tissues are all immersed in the solution.
7. Incubate the tissue in 200-500 µL of blocking buffer for 30 min.
8. Prepare the secondary staining solution: add all secondary antibodies (and lectins if required) to 200-500 µL of staining buffer with desired concentrations (normally 10 µg/mL). Centrifuge the secondary staining solution at 13,000 x g for 5 min. Only use the supernatant if precipitates form.
9. Incubate the tissues in 200-500 µL of secondary antibody solution at 4 °C for 1-2 days.
10. Wash the slides twice with 0.3-0.5% PBST at RT for 5 min each.
11. Incubate with 200-500 µL of DAPI solution for 30 min.
12. Wash the slides three times with PBS at RT for 5 min each.
13. For floating tissue sections, transfer them to glass slides with a glass-dropping pipette. Spread the tissue with a tissue brush and clean the surrounding with wipes if needed.
14. Mount the tissue in a drop of antifade reagents with a glass coverslip and secure it with nail polish.

4. SRS microscope assembly

NOTE: A commercial confocal fluorescence system is used in tandem SRS-fluorescence imaging. More descriptions can be found in a prior report¹⁷. This protocol will focus on the SRS imaging side using narrowband excitation.

1. Prepare a vibration-isolated optical table in a room with temperature control.
2. Place a synchronized dual-laser system (pump and Stokes) on the optical table (Figure 2A) with a chiller connected.
   NOTE: The fundamental laser in the dual-laser system provides an output pulse train at 1064 nm with 6-ps pulse width and 80-MHz repetition rate. The Stokes beam is from the fundamental laser. The intensity of the Stokes beam was modulated sinusoidally by a built-in electro-optic amplitude modulator (EOM) at 8 MHz with a modulation depth of more than 90%. The other portion of the fundamental laser is frequency-doubled to 532 nm, which is further used to synchronously seed a picosecond optical parametric oscillator (OPO) to produce a mode-locked pulse train with 5-6 ps pulse width (the idler beam of the OPO is blocked with an interferometric filter). The output wavelength of the OPO is tunable from 720-950 nm, which serves as the pump beam.
3. Mount the mirrors (wavelength range: 750-1100 nm), dichroic beam splitters (DBS, 980 nm long-pass filter, rectangular), and lens (achromatic, AR coating for 650-1050 nm) to their respective mounts. Use very stablekinematic mirror mounts for the mirrors and dichroic beam splitters.
4. Measure the height of the laser output and the beam sizes of the pump and the Stokes beams. Adjust the height of mirrors and lenses to ensure the light will hit the center of all the optical elements.
5. Place mirror M1 on the optical table and make it ~45° to the laser output (Figure 2B). Use the knobs on the kinematic mount to make tip and tilt adjustments. Ensure the light travels at the same height along the length of the table and a straight line with respect to the table.
6. Place and align the dichroic beam splitters (980 nm long-pass filters) and mirrors to split the pump and Stokes beams (Figure 2A-B).
7. Place and align lens pairs (L1, L2, and L3, L4) on each of the beam paths to collimate the beams and expand the beam diameters to match the back pupil of the objective (Figure 2A-B).
8. Use M7 and M8 mirrors to align combined laser beams into the microscope (Figure 2C). Align one beam into the microscope first and use the mirror pairs on the other beam to ensure the spatial overlap of the two beams.
9. Set up the detection part.
   1. Put on an infrared-coated oil condenser (1.4-NA) to collect the forward-going pump and Stokes beams after passing through the specimens (Figure 2C).
   2. Mount a large-area Si photodiode onto a shielded box with BNC connectors (Figure 2E). Add a 64-V DC power supply to the mounted photodiode to increase its saturation threshold and response bandwidth.
   3. Reflect the forward-going light with a 2-inch mirror. Refocus the light onto the photodiode after an optical filter to block the modulating Stokes beam (Figure 2D).
   4. Send the output current of the photodiode to a fast lock-in amplifier terminated with 50 for signal demodulation. Send an 8-MHz trigger to the lock-in amplifier as the reference signal.
   5. Send the in-phase X-component of the lock-in amplifier into the analog interface box of the microscope.
10. Optimize the temporal overlap with the built-in motorized delay stage by measuring the SRS signal of pure D₂O liquid at the microscope.

5. Image acquisition and analysis

1. Perform multi-channel epr-SRS imaging with sequential pump wavelength tuning.
   1. Set laser power to P_pump = 10-40 mW and P_Stokes = 40-80 mW on the laser control panel.
   2. Set pixel dwell time to 2-4 µs and use multiple frames averaging typically 10-20 frames on the microscopy software.
      NOTE: Avoid a combinatorial use of high laser power (P_pump> 40 mW, P_Stokes> 80 mW) and small pixel size (<0.2 µm), which likely cause 'bleaching effect' of Raman dyes due to multiphoton excitation.
   3. Set the time constants of the lock-in amplifier to half of the pixel dwell time.
2. Linear spectral unmixing.
   NOTE: epr-SRS follows a strict linear signal-to-concentration dependence over the entire concentration range; thus, linear spectral unmixing is effective to remove any potential cross-talks between channels. For N-channel epr-SRS measurement with N MARS probes, measured signals (S) can be expressed as S = MC, where C is the MARS probe concentrations, and M is an N x N matrix determined by Raman cross-sections of MARS probes.
   1. Measure matrix M on single-color immuno-eprSRS samples labeled with different MARS probes.
   2. Use equation C = M−1·S to determine the concentration matrix of the MARS probe with multiplex sample signal measurement S.

Wyniki

Figure 3 shows example images of epr-SRS in different samples, including fixed cells (Figure 3A), paraformaldehyde (PFA)-fixed mouse tissues (Figure 3B), and formalin-fixed paraffin-embedded (FFPE) human specimens (Figure 3C). The spatial resolution of SRS microscopy is diffraction-limited, the typical lateral resolution is ~300 nm, and the axial resolution is 1-2 µm using near-infrared light ...

Dyskusje

Here, we present the immuno-eprSRS protocol which is broadly applicable to common tissue types, including freshly-preserved mouse tissues, FFPE human tissues, and frozen mouse tissues. Immuno-eprSRS has been validated for a panel of epitopes in cells and tissues, as listed in Table 1. This one-shot platform is particularly suitable for applications where cyclic strategies do not function well. For example, cyclic fluorescence is demanding for thick tissues as multiple rounds of 3D immunolabeling are unpr...

Materiały

Name	Company	Catalog Number	Comments
16% Paraformaldehyde, EM Grade	Electron Microscopy Sciences	15710
α-tubulin	Abcam	ab18251	Primary antibodies
α-tubulin	BioLegend	625902	Primary antibodies
β-III-tubulin	BioLegend	657402	Primary antibodies
β-III-tubulin	Abcam	ab41489	Primary antibodies
β-tubulin	Abcam	ab131205	Primary antibodies
Agarose, low gellling temperature	Sigma Aldrich	A9414	For brain embedding
Anti-a-tubulin antibody produced in rabbit (α-tubulin)	Abcam	ab52866	Primary antibodies
Anti-Calbindin antibody produced in mouse (Calbindin)	Abcam	ab82812	Primary antibodies
Anti-GABA B receptor R2  antibody produced in guinea pig (GABA B receptor R2)	Millipore Sigma	AB2255	Primary antibodies
Anti-GFAP antibody produced in goat (GFAP)	Thermo Scientific	PA5-18598	Primary antibodies
Anti-Glucagon  antibody produced in mouse (Glucagon)	Santa Cruz Biotechnology	sc-514592	Primary antibodies
Anti-insulin antibody produced in guinea pig (insulin)	DAKO	IR00261-2	Primary antibodies
Anti-MBP antibody produced in rat (MBP)	Abcam	ab7349	Primary antibodies
Anti-NeuN antibody produced in rabbit (NeuN)	Thermo Scientific	PA5-78639	Primary antibodies
Anti-Pancreatic polypeptide (PP) antibody produced in goat- Pancreatic polypeptide (PP)	Sigma Aldrich	SAB2500747	Primary antibodies
Anti-Pdx1 antibody produced in rabbit (Pdx1)	Milipore	06-1379	Primary antibodies
Anti-Somatostatin antibody produced in rat (Somatostatin)	Abcam	ab30788	Primary antibodies
Anti-Vimentin antibody produced in chicken (Vimentin)	Abcam	ab24525	Primary antibodies
Band-pass filter	KR Electronics	KR2724	8 MHz
BNC 50 Ohm Terminator	Mini Circuits	STRM-50
BNC cable	Thorlabs	2249-C	Coaxial Cable, BNC Male / Male
Broadband dielectric mirror	Thorlabs	BB1-E03	750 - 1100 nm
C57BL/6J mice	Jackson Laboratory	000664
Centrifuge
Condenser	Olympus		oil immersion, 1.4 N.A.
Cytokeratin 18	Abcam	ab7797	Primary antibodies
Cytokeratin 18	Abcam	ab24561	Primary antibodies
DC power supply	TopWard	6302D	Bias voltage is 64 V
Dichroic mount	Thorlabs	KM100CL	Kinematic Mount for up to 1.3" (33 mm) Tall Rectangular Optics, Left Handed
Donkey anti-Chicken IgY (H+L)	Jackson ImmunoResearch	703-005-155	Secondary antibodies for MARS conjugation
Donkey anti-Goat IgG (H+L)	Jackson ImmunoResearch	705-005-147	Secondary antibodies for MARS conjugation
Donkey anti-Guinea Pig IgG (H+L)	Jackson ImmunoResearch	706-005-148	Secondary antibodies for MARS conjugation
Donkey anti-Mouse IgG (H+L)	Jackson ImmunoResearch	715-005-151	Secondary antibodies for MARS conjugation
Donkey anti-Rabbit IgG (H+L)	Jackson ImmunoResearch	711-005-152	Secondary antibodies for MARS conjugation
Donkey anti-Rat IgG (H+L)	Jackson ImmunoResearch	712-005-153	Secondary antibodies for MARS conjugation
Donkey anti-Sheep IgG (H+L)	Jackson ImmunoResearch	713-005-147	Secondary antibodies for MARS conjugation
DPBS	Fisher Scientific	14-190-250
EpCAM	Abcam	ab71916	Primary antibodies
Ethanol	Sigma Aldrich	443611
Fast-speed look-in amplifier	Zurich Instruments	HF2LI	DC - 50 MHz
FFPE Kidney Sample	USBiomax	HuFPT072
Fibrillarin	Abcam	ab5821	Primary antibodies
Giantin	Abcam	ab24586	Primary antibodies
Glucagon	Santa Cruz Biotechnology	sc-514592	Primary antibodies
H2B	Abcam	ab1790	Primary antibodies
HeLa	ATCC	ATCC CCL-2
High O.D. bandpass filter	Chroma Technology	ET890/220m	Filter the Stokes beam and transmit the pump beam
Hydrophobic pen	Fisher Scientific	NC1384846
Insulin	ThermoFisher	701265	Primary antibodies
Integrated SRS laser system	Applied Physics & Electronics, Inc.	picoEMERALD	picoEMERALD provides an output pulse train at 1,064 nm with 6-ps pulse width and 80-MHz repetition rate, which serves as the Stokes beam. The frequency doubled beam at 532 nm is used to synchronously seed a picosecond optical parametric oscillator (OPO) to produce a mode-locked pulse train with five~6 ps pulse width (the idler beam of the OPO is blocked with an interferometric filter). The output wavelength of the OPO is tunable from 720–950 nm, which serves as the pump beam. The intensity of the 1,064-nm Stokes beam is modulated sinusoidally by a built-in EOM at 8 MHz with a modulation depth of more than 90%. The pump beam is spatially overlapped with the Stokes beam by using a dichroic mirror inside picoEMERALD. The temporal overlap between pump and Stokes pulse trains is achieved with a built-in delay stage and optimized by the SRS signal of pure D2O at the microscope.
Inverted laser-scanning microscope	Olympus	FV1200MPE
Kinematic mirror mount	Thorlabs	POLARIS-K1-2AH	2 Low-Profile Hex Adjusters
Lectin from Triticum vulgaris (wheat)	Sigma Aldrich	L0636-5 mg
Long-pass dichroic beam splitter	Semrock	Di02-R980-25x36	980 nm laser BrightLine single-edge laser-flat dichroic beamsplitter
MAP2	BioLegend	801810	Primary antibodies
Microscopy imaging software	Olympus	FluoView
NanoQuant Plate	Tecan		For absorbance-based, small volume analyses in a plate reader.
Normal donkey serum	Jackson ImmunoResearch	017-000-121
NucBlue Fixed Cell ReadyProbes Reagent (DAPI)	Thermo Scientific	R37606
Nunc 4-Well Dishes	Fisher Scientific	12-566-300
Objective lens	Olympus	XLPlan N	x25, 1.05-NA, MP, working distance = 2 mm
Paint brush
Periscope assembly	Thorlabs	RS99	includes the top and bottom units, Ø1" post, and clamping fork.
pH meter
Plate reader	Tecan	Infinite 200 PRO	An easy-to-use multimode plate reader. Absorbance measurement capabilities over a spectral range of 230–1000 nm.
ProLong Gold antifade reagent	Thermo Scientific	P36930
PSD95	Invitrogen	51-6900	Primary antibodies
Sephadex G-25 Medium	GE Life Sciences	17-0033-01	gel filtration resin for desalting and buffer exchange
Shielded box with BNC connectors	Pomona Electronics	2902	Aluminum Box With Cover, BNC Female/Female
Si photodiode	Thorlabs	FDS1010	350–1100 nm, 10 mm x 10 mm Active Area
Synapsin 2	ThermoFisher	OSS00073G	Primary antibodies
Tissue Path Superfrost Plus Gold Slides	Fisher Scientific	22-035813	Adhesive slide to attract and chemically bond fresh or formalin-fixed tissue sections firmly to the slide surface (tiisue bindling glass slides)
Triton X-100	Fisher Scientific	BP151-500
Vibratome	Leica	VT1000
Vimentin	Abcam	ab8069	Primary antibodies
Xylenes	Sigma Aldrich	214736