Quantitation of Protein Expression and Co-localization Using Multiplexed Immuno-histochemical Staining and Multispectral Imaging

Podsumowanie

Immunohistochemistry is a powerful lab technique for evaluating protein localization and expression within tissues. Current semi-automated methods for quantitation introduce subjectivity and often create irreproducible results. Herein, we describe methods for multiplexed immunohistochemistry and objective quantitation of protein expression and co-localization using multispectral imaging.

Streszczenie

Immunohistochemistry is a commonly used clinical and research lab detection technique for investigating protein expression and localization within tissues. Many semi-quantitative systems have been developed for scoring expression using immunohistochemistry, but inherent subjectivity limits reproducibility and accuracy of results. Furthermore, the investigation of spatially overlapping biomarkers such as nuclear transcription factors is difficult with current immunohistochemistry techniques. We have developed and optimized a system for simultaneous investigation of multiple proteins using high throughput methods of multiplexed immunohistochemistry and multispectral imaging. Multiplexed immunohistochemistry is performed by sequential application of primary antibodies with secondary antibodies conjugated to horseradish peroxidase or alkaline phosphatase. Different chromogens are used to detect each protein of interest. Stained slides are loaded into an automated slide scanner and a protocol is created for automated image acquisition. A spectral library is created by staining a set of slides with a single chromogen on each. A subset of representative stained images are imported into multispectral imaging software and an algorithm for distinguishing tissue type is created by defining tissue compartments on images. Subcellular compartments are segmented by using hematoxylin counterstain and adjusting the intrinsic algorithm. Thresholding is applied to determine positivity and protein co-localization. The final algorithm is then applied to the entire set of tissues. Resulting data allows the user to evaluate protein expression based on tissue type (ex. epithelia vs. stroma) and subcellular compartment (nucleus vs. cytoplasm vs. plasma membrane). Co-localization analysis allows for investigation of double-positive, double-negative, and single-positive cell types. Combining multispectral imaging with multiplexed immunohistochemistry and automated image acquisition is an objective, high-throughput method for investigation of biomarkers within tissues.

Wprowadzenie

Immunohistochemistry (IHC) is a standard lab technique for detection of protein within tissue, and IHC is still widely used in both research and diagnostic pathology. The evaluation of IHC staining is often semi-quantitative, introducing potential bias into interpretation of results. Many semi-quantitative approaches have been developed which incorporate both staining intensity and staining extent into final diagnosis ^1-4. Other systems include scoring intensity and subcellular location in order to better localize expression ⁵. Incorporation of average scores from multiple viewers is often utilized in order to minimize the effects of single viewer bias ⁶. Despite these efforts, subjectivity in analysis still remains, particularly when evaluating the extent of staining ⁷. Protocol standardization and minimizing subjectivity from human input is paramount to creating accurate, reproducible IHC results.

There are other options besides IHC for determining protein expression within tissues. Within the research setting, immunohistochemistry has traditionally been viewed as a means to examine protein localization ⁸, while other techniques such as immunoblotting are viewed as gold standard for investigating protein expression. Determining tissue or cell compartment-specific expression is difficult without incorporating advanced techniques such as cell fractionation or laser capture microdissection ^9,10. The use of fluorescent antibodies on tissue slides offers a reasonable compromise, but background autofluorescence due to NADPH, lipofuscins, reticular fibers, collagen, and elastin can make accurate quantitation difficult ¹¹.

Automated computational pathology platforms are a promising direction for more objective quantitation of pathology staining ^12-15. Combining multispectral imaging with tissue microarrays facilitates high-throughput analysis of protein expression in large sample sizes. With these techniques, analysis of protein co-localization, staining heterogeneity, and tissue and subcellular localization is possible while substantially reducing both inherent biases and time necessary for analysis, while returning data in a continuous rather than categorical format ¹⁶. Therefore, the purpose of this study was to demonstrate the utility of and methodology for performing multiplexed immunohistochemistry with analysis, using multispectral imaging software.

This protocol is written for manual, multiplex immunohistochemical staining of a single tissue section slide with four optimized monoclonal antibodies. As a representative experiment, nuclear anti-rabbit estrogen receptor alpha (ERα) and androgen receptor (AR) are multiplexed with membrane-bound anti-mouse CD147 and membrane-bound anti-mouse E-cadherin. Any antibody of choice may be substituted for the antibodies listed herein, but each combination of antibodies requires separate optimization. Pre-treatment for all the antibodies must be identical. The AR and CD147 antibodies should be optimized individually and then as a cocktail. Each antibody is detected using a biotin-free polymer system and one of 4 unique chromogens.

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Protokół

     NOTE: The protocol herein describes staining and analysis of a tissue microarray (TMA), described previously ^12,17,18. The 4 µm thick TMA section was obtained from a paraffin block using a standard microtome. 

     NOTE: A spectral library for the 4 chromogens and counterstain should be created for image quantitation. In order to do this, the optimized protocol for each individual antibody should be run with one antibody per slide, minus the final counterstain. A fifth slide should be stained with hematoxylin to generate the 5 images needed to create the spectral library.

1. Multiplex Immunohistochemistry

1. Bake slides in a 60 °C oven for 20 min. Using a chemical fume hood, immerse slide in 100% xylene. Repeat for 2 changes of xylene. Immerse slide in 100% ethanol for 5 min. Repeat with fresh 100% ethanol.
2. Immerse slide in 95% ethanol for 3 min. Repeat with fresh 95% ethanol. Immerse slide in 70% ethanol for 3 min. Immerse slide in distilled water for 3 min. Repeat with fresh distilled water. Tap slide vertically to drain water from the slide. Apply 200 µl of ready-to-use endogenous peroxidase blocker for 5 min.
3. Drain peroxidase blocker from slide and immerse in 45 ml ready-to-use retrieval buffer (pH less than 7.0). Place slide container in a pressure cooker and start program set to 124 °C for 4 min. Allow pressure cooker to cool for 20 min. before opening.
4. Remove container of retrieval buffer and allow to cool additional 10 min. Rinse slide in distilled water for 10 min. Drain water from the slide and carefully delineate the tissue on the slide with a hydrophobic barrier pen.
5. Add 200 µl of phosphate buffered saline (PBS).Transfer slide to a flat receptacle with lid (incubation chamber) containing moist gauze.
6. Prepare 1 liter of 1x Tris-buffered saline with Tween-20 (TBST) by diluting 50 ml of 20x Tris buffered saline containing 1% Tween-20 and 950 ml distilled water.
7. Drain PBS from slide and apply 200 µl of 1x TBST. Incubate 2 min. Drain TBST from slide and return slide to incubation chamber. Apply 200 µl of ready-to-use universal protein block, close chamber and incubate for 7 min.
8. Drain protein block and return slide to incubation chamber. Dilute anti-ERα antibody 1:400 by adding 0.6 µl of antibody to 239.4 µl of antibody diluent. Apply 200 µl of diluted antibody to slide and close chamber.
9. Incubate slide at room temperature for 2 hours. Drain antibody from slide and rinse with TBST followed by immersion for 5 min in TBST.
10. Drain TBST from slide and return slide to incubation chamber. Apply 200 µl of ready-to-use goat anti-rabbit horseradish peroxidase polymer and close chamber. Incubate for 30 min. at room temperature. Rinse slide with TBST and place slide in container of TBST for 5 min.
11. Prepare brown horseradish peroxidase-3,3'-diaminobenzidine (HRP-DAB) chromogen by adding 8 µl of DAB chromogen to 250 µl DAB substrate buffer and mixing well.
12. Drain TBST from slide, return slide to incubation chamber and apply 200 µl of brown HRP-DAB chromogen for 6 min. Thoroughly rinse the slide with distilled water and place slide in a container of distilled water.
13. Mix the denaturing solution by combining 50 µl of the first elution reagent with 150 µl of the second buffer reagent. Drain water off the slide and apply diluted denaturing solution to the slide for 3 min. at room temperature. Decant and rinse denaturing reagent with TBST. Immerse slide in TBST for 5 min.
14. Prepare AR/CD147 antibody cocktail by diluting 4.2 µl of anti-AR antibody and 2.8 µl of anti-CD147 antibody with 203 µl of antibody diluent. Drain TBST from the slide, return slide to incubation chamber and apply 200 µl of AR/CD147 cocktail to the slide. Close chamber and incubate for 1 hr at room temperature. Rinse slide with TBST and immerse in TBST for 5 min.
15. Drain TBST, return slide to incubation chamber and apply 200 µl of ready-to-use goat anti-rabbit alkaline phosphatase polymer. Close chamber and incubate slide for 30 min. at room temperature. Rinse slide with TBST and immerse in TBST for 5 min.
16. Prepare red alkaline phosphatase chromogen by adding 3.2 µl of red chromogen to 250 µl red chromogen buffer and mix well.
17. Drain TBST from slide and return slide to incubation chamber. Apply 200 µl of diluted red alkaline phosphatase chromogen to the slide, close chamber and incubate for 7 min.
18. Drain chromogen and thoroughly rinse slide with distilled water. Place slide in a container of distilled water for 5 min. Drain water from the slide, rinse with TBST and return to incubation chamber. Apply 200 µl goat anti-mouse-HRP polymer to the slide and close chamber. Incubate for 30 min. at room temperature.
19. Drain polymer from the slide and rinse with TBST. Place slide in TBST for 5 min. Prepare 200 µl of purple HRP-linked chromogen by adding 3.2 µl of the stabilizing reagent to 250 µl of the buffer and mix well. Add 3.2 µl of purple chromogen and mix well, then 3.2 µl of the hydrogen peroxide reagent and mix well.
20. Drain TBST off slide and apply 200 µl of prepared purple chromogen to slide and incubate for 7 min. at room temperature. Rinse slide with distilled water and place slide in a container of distilled water for 5 min.
21. Mix the denaturing solution by mixing 50 µl of the first elution reagent with 150 µl of the second buffer reagent. Drain water off the slide and apply diluted denaturing solution to the slide for 3 min. at room temperature.
22. Rinse denaturing reagent off with TBST. Place slide in container of TBST for 5 min. Dilute anti-E-cadherin antibody to 1:200 by adding 1.1 µl antibody to 218.9 µl antibody diluent. Drain the TBST from the slide, return slide to incubation chamber and apply 200 µl of E-cadherin to the slide. Close chamber and incubate 30 min. at room temperature.
23. Rinse slide with TBST and place slide in container of TBST for 5 min. Drain the TBST from slide, return slide to incubation chamber and apply 200 µl goat anti-mouse HRP polymer. Incubate at room temperature for 30 min. Rinse slide with TBST and place slide in container of TBST for 5 min.
24. Prepare black HRP-linked chromogen by adding 8 µl of chromogen to 250 µl buffer. Apply 200 µl chromogen to slide and develop for 2 min. Thoroughly rinse slide with distilled water and immerse in container of distilled water.
25. Dilute hematoxylin by adding 40 µl hematoxylin to 200 µl distilled water. Drain water from slide and apply 200 µl of diluted hematoxylin to slide for 30 seconds. Rinse slide thoroughly running tap water for 2 min., then rinse in distilled water for 30 seconds. Place slide in a 60 °C oven for 15-30 min.
26. Immerse slide in freshly prepared 100% xylene for 30 seconds, wipe excess xylene off and add one drop of permanent mounting media. Coverslip with a No. 1.5 coverslip.

2. Automated Image Acquisition and Analysis

1. Load stained slides onto an automated slide scanner. Based on the diameter, separation, and number of TMA cores, create an automated scanning protocol according the manufacturer's instruction manual.
2. Open multispectral imaging software to build a spectral library from control slides stained with individual chromogens and the hematoxylin stained slide. Open an image cube acquired from a control slide and select four to five positively stained areas to optically define that chromogen. Repeat with image cubes from other control slides until a complete spectral library representing all chromogens is created, and then save the spectral library.
3. Begin a new project within multispectral imaging software. Select "Multispectral (.im3)" for the image format option and "Brightfield" for the sample format. First, configure the project by choosing desired options: "Segment Tissue", "Find Features", "Phenotyping", "Score" and "Export". At this point, the image resolution can be changed to expedite analysis time if desired.

3. Tissue Segmentation

1. Import the previously created spectral library and select all chromogens to be included in analysis.
2. Open image cubes to be included in the training data set by selecting the "Open Image Cube" option. To ensure training accuracy, select at least 18% of the total number of images to be analyzed. Choose images that represent all disease states to increase segmentation accuracy. This portion of images is called the training set of images.
3. White balance images in the training set by selecting the eye dropper tool and choosing an area in one image that is white.
4. Select "Advance" button to move to tissue segmentation. Use the "Tissue Categories" panel to choose tissue types to be analyzed (i.e. "tissue" and "non-tissue"). For more accurate protein tissue localization, multiple tissue categories can be used (i.e. "epithelia," "stroma," and "non-tissue").
5. Begin creating the algorithm and defining tissue categories by drawing around groups of cells within training images. When finished with one tissue category, repeat for other tissue categories. Be sure to choose groups of cells within images that are characteristic of that tissue category type.
6. Repeat this process for all images within the training set of images.
7. Select components (chromogens) to be included in training for the "Tissue Segmenter". When performing analysis of brightfield immunohistochemistry images, all components are normally included in training. Include abundant negative staining images in the training set to avoid bias during this step.
8. Choose an appropriate "Pattern Scale" for training the tissue segmenter. Under 20X magnification, a large pattern scale is typically appropriate. When working with tissues with a fine architecture under higher magnification, a smaller pattern scale is more appropriate.
9. Select the "Train Tissue Segmenter" button to start training the tissue segmenter. Observe a pop-up box displaying accuracy reflecting the proportion of pixels within training regions that are properly classified.
   NOTE: The software continually attempts to improve the accuracy of the algorithm until manually stopped. We have previously demonstrated that training on 18% of images results in 97% training accuracy ¹².
10. After the tissue segmenter is trained, choose an appropriate segment resolution. Segment resolution corresponds to time required to segment images, with coarse resolution requiring less time and fine resolution requiring more time.
11. Segment the entire training set of images by clicking "Segment Images". Allow the software adequate time to apply the algorithm to all training images. When finished, review the training set to find any misclassified tissue with the current training algorithm.
12. To fine tune the tissue segmentation process, add, edit, or remove tissue training regions. Use the "trim edges" option if pixels extend on the edges of one tissue category into another. If small groups of pixels are misclassified, adjust the threshold on the minimum segment size.
13. When edits are completed, select "Segment Images", this will re-train the tissue segmenter to create a new algorithm for tissue segmentation. The previous algorithm is automatically saved and can be returned to if needed.
14. When confident with tissue segmentation algorithm results, advance to cell segmentation by selecting the "Advance" button.

4. Cell Segmentation

1. Choose the subcellular compartments to be included in cell segmentation. Ensure that "Nuclei" is already selected to choose "Cytoplasm" or "Membrane".
   NOTE: "Membrane" segmentation should only be chosen when a membrane-specific protein marker was included in IHC, such as E-cadherin.
2. Within the "Nuclei" tab, there are several options. Begin by choosing appropriate settings for nuclear segmentation (see step 4.3). Choose whether individual or all tissue categories will be included in segmentation.
3. Select an approach for nuclear segmentation
   1. Select the counterstain "Pixel-Based (Threshold)" approach for a simplified method for obtaining good results without knowing much about image processing settings.
      NOTE: This often makes a good first choice. When selecting an approach, "Pixel-Based (Threshold)" is more appropriate when there is a reliable nuclear counter-stain, while "Object-Based" should be used if there is a lack of consistent nuclear counterstain.
   2. Select the "Pixel-Based (Threshold)" approach when there is a reliable nuclear counterstain.
      NOTE: This approach is purely pixel-based. This approach can also be used for other image analysis needs that can be satisfied with a simple threshold, such as detecting all pixels within a tissue category that stain positive for an IHC stain.
   3. Select the Object-Based approach if the nuclear counterstain does not provide consistent and specific staining of nuclear objects, and more advanced morphometry-based approaches are needed to detect nuclei.
   4. Select "Components for Nuclear Segmentation", "Nuclear Size", and "Clean-up" if user wishes to further define nuclei segmentation settings.
4. Select cytoplasm shape parameters
   1. Select the "Advance" button to move to cytoplasm segmentation.
      NOTE: There are several options within cytoplasm segmentation to choose from. The option termed "inner distance to nucleus" is pixel based. It reflects the distance between the outside of the nucleus and the inside of the cytoplasm. Increasing this value decreases the probability that nuclear signal crosses over into the cytoplasm compartment.
   2. Next select, "outer distance to nucleus".
      NOTE: This is also pixel based. The outer distance to nucleus reflects the distance between the outside of the nucleus and the outside of the cell. This value can be set large or small enough to include or exclude membrane signals if desired.
   3. Next select, "minimum size".
      NOTE: The minimum size, pixel based, reflects the minimum cytoplasm sample size to be included in analysis. If the cytoplasm size is smaller in a particular cell such as when cells are tightly packed together, this cytoplasm segmentation is excluded from analysis.
   4. Select the next option, "Component" with "Primary", "Secondary", and select "Tertiary" as secondary options.
      NOTE: Here one may choose a specific cytoplasm marker. Similar to nuclear segmentation, if a specific cytoplasmic IHC marker has been used, this component can be used to define the cytoplasm by finding a minimum threshold value. This assists in defining the cytoplasm but is not necessary for acceptable accuracy.
   5. Moving to the last of the three tabbed options is "Membrane". Here, the user defines the membrane compartment with a protein marker. Choose "Primary", "Secondary", and/or "Tertiary" for each membrane specific marker used. Adjust "Full Scale OD" to find a minimum threshold or a positive for each marker on cell membranes.
   6. Continuing under the "Membrane" tab and select the option "Maximum Cell Size".
      NOTE: This is the distance to membrane value, in pixels, which specifies the maximum size of the cells. A value of 12 is normally appropriate for images taken at 20X magnification.
   7. After selecting all the options, select "Segment Image" or "Segment All". Apply the settings to images and observe them "individually" or in "Gallery" mode.
      NOTE: Adjust settings and thresholds if necessary, and re-segment until satisfied with cell segmentation results in the training set of images.

5. Phenotyping of Cells

       NOTE: Accurate cell segmentation is required in order to obtain accurate cell phenotyping, and the phenotyping feature is trainable.

1. Use the "Add" button to add phenotypes to the "Phenotypes" list. Users can select a color for the phenotype.
2. Click on "Edit Phenotypes" to assign a phenotype to a cell. Click on a particular cell to bring up a drop-down menu, allowing user to choose the phenotype and then move on. Identify at least five (5) cells in each phenotype in order to proceed. Choosing 25 or more cells of each phenotype is needed to achieve optimal results.

6. Scoring IHC and Co-Localization

1. Choose "Advance" to move to the "Score IHC or IF" step. Choose a "Tissue Category" to score.
   NOTE: Only one tissue category can be scored during a particular analysis, but if scoring results in another tissue category are desired, the analysis can be repeated later with different settings.
2. Choose a desired "Scoring" type.
   NOTE: Positivity creates two bins (positive and negative) for a component of interest, while double positivity is used for co-localization analysis. Other options include 4-bin, 10-bin, and 50-bin analyses for a marker of choice.
3. Choose the cell "Compartment" to be used in scoring analysis.
4. Similar to finding a minimum threshold for the primary nuclear component, select "View Component Data" and move cursor over the training images to find appropriate optical density minimum thresholds of staining for positive cells for the component(s) of interest.
5. If intensely stained cells are to be excluded, lower the threshold max to an appropriate level. Otherwise, use the auto button to choose a threshold maximum for analysis.
6. Choose training images to score in order to validate thresholding values.
   NOTE: The percentage of cells within a particular bin will be returned and can be compared by visual inspection or manual counting. Once complete, select "Advance" to proceed to "Export" step.

7. Applying the Algorithm and Batch Analysis

1. Test the algorithm created through tissue segmentation, cell segmentation, and scoring values by exporting the data for the training set. Follow prompts to create a new folder for the export directory. Select images and tables to be created and included in analysis. Perform the analysis by selecting "Export for All".
2. Tables are exported in tab-separated text files and can be opened in most data analysis programs.
3. When analysis is complete, view cell segmentation and scoring data for images with both high and low staining to evaluate accuracy of settings.
4. When satisfied with settings, apply the algorithm created from the training set of images to the entire set of images through batch analysis. Click on the "Batch Analysis" tab and the opened algorithm will be copied from the active project.
5. Choose a new export directory and select which images and tables are to be included in the analysis. Under the input files option, select "Add Images" and choose all images to be included in the batch analysis.
6. Perform the analysis by selecting the "Run" option. As with the analysis of the training set, this step will require a variable amount of time, depending on particular settings and number of images included in the analysis.
7. When completed, advance to the "Review/Merge" tab. The batch directory defaults to the export directory from the batch analysis and can be changed if desired. Select "Include All" and select "Merge" to create data sheets with summary data for analysis.

8. Analysis of Exported Data

1. Open exported tables in data analysis software and remove or hide data columns that are irrelevant to analysis, such as minimum and maximum values for each component. The primary data used in analysis is in the mean optical density column for every component.
2. Review exported segmentation maps and raw images to determine which samples or TMA cores are to be excluded from analysis. Tissue percentage values assist in determining whether a sample should be included or not, with an arbitrary cutoff of <5% used most often for exclusion criteria.
3. Remove irrelevant data or rows containing samples to be excluded from data analysis.
4. Use protein quantification data to investigate changes in disease state or the relationship with clinico-pathological characteristics of disease ^12,18-21.

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Wyniki

In Figure 1, training is performed on prostate tissues to segment images into epithelial and stromal portions, along with the non-tissue compartment. By using the epithelial membrane marker E-cadherin, cell segmentation was performed to separate the nucleus, cytoplasm, and membrane portions, shown in Figure 2.

In one experiment, we used multiplexed IHC to investigate the expression and localizat...

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Dyskusje

The use of traditional immunohistochemistry for evaluating protein expression is limited by subjective, semi-quantitative methods of analysis ^22,23. Advance platforms have been created for high-throughput analysis of biomarker expression and localization. Detailed segmentation of both tissue and subcellular compartments allows users to study biomarker expression, localization, and co-localization with other markers of interest. In previous studies, we have demonstrated the utility of IHC and multispectral imag...

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Materiały

Name	Company	Catalog Number	Comments
Xylene	Fisher Chemical	X3F1GAL	NFPA rating: Health – 2, Fire – 3 , Reactivity – 0
Ethyl Alcohol-200 proof	Fisher Scientific	4355223	NFPA rating: Health – 0, Fire – 3 , Reactivity – 0
Tris Base	Fisher Scientific	BP152-500	NFPA rating: Health – 2, Fire – 0 , Reactivity – 0
Tris Hydroxymethyl aminomethane HCl	Fisher Scientific	BP153-1	NFPA rating: Health – 2, Fire – 0 , Reactivity – 0
Tween 20	Chem-Impex	1512	NFPA rating: Health – 0, Fire – 1 , Reactivity – 0
Phosphate-buffered saline	Fisher Scientific	BP2944-100	NFPA rating: Health – 1, Fire – 0 , Reactivity – 0
Peroxidazed	Biocare Medical	PX968	Avoid contact with skin and eyes. May cause skin irritation and eye damage.
Estrogen Receptor alpha	Thermo Fisher Scientific-Labvision	RM9101	Not classified as hazardous
Androgen Receptor	SCBT	sc-816	Not classified as hazardous
CD147	Biodesign	P87535M	Not classified as hazardous
E-cadherin	Dako	M3612	Not classified as hazardous
Renoir Red Andibody Diluent	Biocare Medical	PD904	It is specially designed to work with Tris-based antibodies
DeCloaking Chamber	Biocare Medical	Model DC2002	Take normal precautions for using a pressure cooker
Barrier pen-Immuno Edge	Vector Labs	H-4000
Denaturing Kit-Elution step	Biocare Medical	DNS001H	Not classified as hazardous
Mach 2 Goat anti-Rabbit HRP Polymer	Biocare Medical	RHRP520	Not classified as hazardous
Mach 2 Goat anti-Rabbit AP Polymer	Biocare Medical	RALP525	Not classified as hazardous
Mach 2 Goat anti-Mouse HRP Polymer	Biocare Medical	M3M530	Not classified as hazardous
Betazoid DAB Chromogen Kit	Biocare Medical	BDB2004	1. DAB is known to be a suspected carcinogen. 2. Do not expose DAB components to strong light or direct sunlight. 3. Wear appropriate personal protective equipment and clothing. 4. DAB may cause sensitization of skin. Avoid contact with skin and eyes. 5. Observe all federal, state and local environmental regarding disposal
Warp Red Chromogen Kit	Biocare Medical	WR806	Corrosive. Acid that may cause skin irritation or eye damage.
Vina Green Chromogen Kit	Biocare Medical	BRR807	Harmful if swallowed
Bajoran Purple Chromogen Kit	Biocare Medical	BJP807	Flammable liquid. Keep away from heat, flames and sparks. Harmful by ingestion or absorption. Avoid contact with skin or eyes, and avoid inhalation.
Cat Hematoxylin	Biocare Medical	CATHE	Purple  solution  with  a  mild  acetic  acid  (vinegar)  scent.  May  be  irritating  to  skin  or  eyes.  Avoid  contact  with  skin  and  eyes.  Avoid  ingestion.
XYL Mounting Media	Richard Allen	8312-4	NFPA rating: Health – 2, Fire – 3 , Reactivity – 0
1.5 Coverslips	Fisher Brand	22266858	Sharp edges
Incubation (Humidity)Chamber	obsolete	obsolete	Multiple vendors available
Convection Oven	Stabil- Therm	C-4008-Q
Background Punisher Blocking Reagent	Biocare Medical	BP974	This product is not classified as hazardous.
inForm software	PerkinElmer	CLS135781	Primary multispectral imaging software used in manuscript
Nuance software	PerkinElmer	Nuance EX	Software used for making spectral libraries within manuscript
Vectra microscope and slide scanner	PerkinElmer	VECTRA	Automated slide scanner and microscope for obtaining IM3 image cubes