Journal of Histochemistry and Cytochemistry, Vol. 51, 151-158, February 2003, Copyright © 2003, The Histochemical Society, Inc.


ARTICLE

Computerized Quantification of Tissue Vascularization Using High-resolution Slide Scanning of Whole Tumor Sections

Christophe F. Chantraina, Yves A. DeClercka, Susan Groshenb, and George McNamarac
a Division of Hematology–Oncology, Department of Pediatrics and Department of Biochemistry and Molecular Biology, Childrens Hospital Los Angeles and USC Keck School of Medicine
b Department of Preventive Medicine, USC Keck School of Medicine
c Congressman Dixon Cellular Imaging Core, Childrens Hospital Los Angeles Research Institute, Los Angeles, California

Correspondence to: Yves A. DeClerck, Div. of Hematology–Oncology, MS #54, Childrens Hospital Los Angeles, 4650 Sunset Boulevard, Los Angeles, CA 90027. E-mail: declerck@hsc.usc.edu


  Summary
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Assessment of tissue vascularization using immunohistochemical techniques for microvessel detection has been limited by difficulties in generating reproducible quantitative data. The distinction of individual blood vessels and the selection of microscopic fields to be analyzed remain two factors of subjectivity. In this study, we used imaging analysis software and a high-resolution slide scanner for measurement of CD31-immunostained endothelial area (EA) in whole sections of human neuroblastoma xenograft and murine mammary adenocarcinoma tumors. Imaging analysis software provided objective criteria for analysis of sections of different tumors. The use of the criteria on images of entire tumor section acquired with the slide scanner constituted a rapid method to quantify tumor vascularization. Compared with previously described methods, the "hot spot" and the "random fields" methods, EA measurements obtained with our "whole section scanning" method were more reproducible with 8.6% interobserver disagreement for the "whole section scanning" method vs 42.2% and 39.0% interobserver disagreement for the "hot spot" method and the "random fields," respectively. Microvessel density was also measured with the whole section scanning method and provided additional data on the distribution and the size of the blood vessels. Therefore, this method constitutes a time efficient and reproducible method for quantification of tumor vascularization.

(J Histochem Cytochem 51:151–158, 2003)

Key Words: angiogenesis, vascularization, endothelial area, CD31, immunohistochemistry, slide scanner, quantification


  Introduction
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

SEVERAL immunohistochemical (IHC) techniques using anti-CD31 (PECAM-1), anti-CD34, or anti-Factor VIII antibodies have been developed to detect endothelial cells in tumor tissues (Vermeulen et al. 1996 ). Evaluation of tumor vascularization by these techniques has been hampered by difficulties in obtaining reproducible quantitative data. Tumor vascularization is usually quantified by determining microvessel density (MVD), which consists of a visual count of blood vessels performed under high-magnification light microscopy (Weidner et al. 1991 ). This method remains variable and poorly reproducible for two reasons (Vermeulen et al. 1996 ; Fox et al. 2000 ). First, the counting procedure relies on the subjective distinction of individual vessels by the observer. This distinction may be particularly difficult in areas of tangled capillaries or in areas where a single tortuous vessel can be sectioned several times and, depending on the observer, counted as one or multiple microvessels (Simpson et al. 1996 ). Different methods based on computerized image analysis have been developed to quantify IHC staining (Lehr et al. 1997 ) and have therefore been proposed to eliminate the subjective distinction of microvessels. Measurement of endothelial area (EA) corresponding to the surface of immunostained endothelial structure (Simpson et al. 1996 ; Schoell et al. 1997 ), microvessel perimeter, and microvessel area, consisting of the EA plus the vessel lumen (Barbareschi et al. 1995 ), has been used as a more accurate index of tumor vascularization. However, these methods do not eliminate a second factor of variability, which is the selection of the tissue area to be analyzed. Microvessel quantification is usually performed, either on vascular hot spots corresponding to the most vascularized area (Weidner et al. 1991 ), or on randomly chosen microscopic fields (Oh et al. 2001 ). The selection of vascular hot spots is subjective and depends on the experience and the training of the observer (Vermeulen et al. 1997 ). Vascularization quantification on randomly chosen microscopic fields is dependent on the arbitrary selection of a limited number of fields in a restricted area of a tumor section and does not take into consideration the heterogeneous distribution of microvessels in tumor tissue (Vermeulen et al. 1996 ). Here we propose to use imaging analysis software and a high-resolution slide scanner to quantify tumor vascularization in whole tumor sections in a time-efficient and reproducible manner.


  Materials and Methods
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Tumor Tisssue Samples
Vascularization was quantified on tissue sections of two types of tumor obtained from animal models. Five suprarenal tumors were collected from a xenograft model of human neuroblastoma previously reported by us, in which a fragment of neuroblastoma tumor is surgically implanted into the adrenal gland of immunocompromised mice (Moats et al. 2001 ). Five mammary adenocarcinoma tumors were obtained from a transgenic murine model in which overexpression of the Wnt-1 proto-oncogene in the mammary gland induces early duct hyperplasia and transformation into adenocarcinoma (Li et al. 2000 ). Tumors were carefully dissected, embedded in OCT, snap-frozen in liquid nitrogen, and stored at -70C.

Immunohistochemistry for CD31
Detection of blood vessels was performed by IHC for CD31. Frozen 7-µm sections brought to room temperature (RT) were fixed in acetone and blocked in 5% goat serum supplemented with 2.5% BSA. Sections were incubated overnight at 4C in the presence of a rat anti-mouse CD31 antibody (dilution 1:50) (product 019151D; Pharmingen, San Diego, CA). A biotinylated goat anti-rat antibody (product 31831; Pierce, Rockford, IL) was used as a secondary antibody (dilution 1:200) for 1 hr at RT. The sections were then processed with an avidin–biotin–peroxidase complex (Vectastain ABC kit; Vector Laboratories, Burlingame, CA), revealed in the presence of 3,3'-diaminobenzidine tetrahydrochloride (DAB; Sigma, St Louis, MO), and counterstained with methylgreen (1%).

Digital Image Acquisition
Digital images of microscopic fields of tumor tissue (x5 and x20 Plan objective) were acquired with a Leica DM RA microscope (Leica Microsystems; Wetzlar, Germany) and an Olympus DP11 color digital CCD camera (Olympus; Melville, NY) with settings of HQ 1712 x 1368 pixels JPEG, ISO 400, 3000 K color temperature (0.05-sec exposure for x20, 0.04 sec for x5 objective). Images of whole tumor sections were acquired with a Polaroid SprintScan 4000 35-mm film slide scanner and PolaColor Insight software (Polaroid; Cambridge, MA) connected to a Compaq Professional Workstation SP750 computer (1 GHz Pentium III CPU, 1 Gb RAM) (Compaq; Houston, TX). Microscopic slides were held in the scanner by a PathScan Enabler 4000 microscope slide holder (Meyer Instrument; Houston, TX). Slides were scanned at 4000 dpi resolution with scale 100%, autofocus on for final scan, unsharp mask amount 50, radius 2, threshold 5, dust reduction off, as recommended in the PathScan instructions. In one neuroblastoma tumor, an additional image of the entire tumor section was obtained by digital montage of individual x5 Plan objective microscopic field pictures assembled using Adobe Photoshop 6.0 (Adobe Systems; San Jose, CA). Montage and scanned images were saved as 24-bit color TIFF format. Before analysis, a shading correction was performed on all the microscopic field images. For each slide, a white reference image corresponding to a blank area was captured using microscope and camera settings described above. The tumor images were corrected using the equation <250 x specimen/white reference> in the <Arithmetic> command of Metamorph 4.6 imaging software (Universal Imaging; Downingtown, PA). This correction removed any dust shadow and scaled the light to the same intensity range, resulting in consistent thresholding over multiple image acquisition sessions. White balancing for the slide scanner was more constant at acquisition time and scanned images did not require shading correction.

Vascularization Quantification
MetaMorph 4.6 software was used for computerized quantification of immunostained vascular structures. DAB-positive pixels were selectively detected and uniformly displayed with red pixel overlay using the threshold function. Threshold parameters were defined by successively adding regions with heavily DAB staining and deleting regions of counterstaining and background without DAB from the threshold with the command <Threshold Image> from the <Measure> menu (Fig 1A). These last two steps were repeated until all the DAB-positive pixels were selectively thresholded. Independent threshold settings were defined for analysis of the microscope images and the scanned images. The threshold area corresponding to the EA was measured with the <Region Measurement> function. For the whole section images, the EA was selectively measured on the tumor tissue delineated by using the <Trace Region> command of MetaMorph 4.6. Neighboring kidney, peripheral surrounding tissues, and necrotic areas were excluded from the selection (Fig 1B). The EA was expressed as a ratio of DAB-positive thresholded pixels compared to the number of pixels per image (microscopic field images) or per selected region (whole section images). For some tumor sections, the MVD was also quantified with the <Integrated Morphometry Analysis> command of MetaMorph 4.6. Using the total area classifier filter, every separate cluster of thresholded pixels with a minimal size of 5 pixels for the scanned image and a minimal size of 200 pixels for the microscopic field image was defined as one object. The number of objects, the surface, and the total surface (corresponding to the object surface plus the lumen) of each object were measured on an entire tumor region delineated as for the EA quantification.



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Figure 1. MetaMorph 4.6 screen display during computerized endothelial area quantification. (A) Definition of threshold settings on x20 objective microscopic field image. Threshold sensitivity was set to 5. DAB-positive region and negative counterstained region were selected and respectively <Add to Threshold> or <Delete from Threshold> using the <Threshold Image> window from <Measure> menu. (B) Endothelial area measurement on entire neuroblastoma tumor region. A relevant entire tumor region was drawn and selected by avoiding surrounding structures such as kidney and adrenal gland. A predefined threshold was then loaded and the threshold area was measured using the <Region Measurement> command from <Measure> menu.

Statistical Analysis
Variability of the whole section scanning method was compared to the variability of the hot spot method and the random fields method. For each method, a two-way random effect analysis of variance was used to estimate three sources of variability: due to different tissues, due to different observers, and unexplained variability (which was confounded with the tissue x observer interaction effect). The mean sums of squares were used to estimate the variance components. Ratios of the standard deviation and the coefficient of variation (standard deviation divided by the average of all 15 observations for the method and multiplied by 100) were used to summarize the variability associated with each method. A second estimate of interobserver variability was based on the percent disagreement, which was calculated for each tumor and each method by dividing the largest pairwise difference between observers by the average EA for that tumor and method and then multiplying by 100.


  Results
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Analysis of Different Tumor Tissues with the Same Threshold Setting
First we evaluated whether the threshold setting defined for one tumor section immunostained for CD31 could be used for analysis of sections of other tumors with the same level of sensitivity and specificity. The threshold setting defined on images of x20 objective microscopic fields of a first neuroblastoma tumor (tumor N1) was applied to microscopic field images of sections of four other neuroblastoma tumors similarly processed (tumors N2, N3, N4, N5). Visual examination of images of these five tumors with and without the threshold did not detect any DAB-negative thresholded pixels (false-positive) or DAB-positive unthresholded pixels (false-negative) (Fig 2). In the same manner, the threshold setting defined on an image of a section of neuroblastoma tumor N1 acquired with the slide scanner was applied on similar scanned images of neuroblastoma tumors N2, N3, N4, and N5. As observed for the microscopic field images, examination of images with and without threshold did not reveal a difference of sensitivity or specificity among the five sections analyzed (data not shown). Therefore, the threshold setting determined in one tissue sample can be used for analysis of other similar tissue samples.



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Figure 2. Sensitivity and specificity of computerized CD31 detection in sections of different neuroblastoma tumors. Threshold settings were defined on x20 objective field image of neuroblastoma tumor N1 (A,B) and then applied to x20 objective field images of other neuroblastoma tumors N2, N3, N4, N5 similarly processed (C–J). Comparison of original images (A,C,E,G,I) to images with threshold (B,D,F,H,J) did not detect any DAB-negative thresholded pixels or DAB-positive unthresholded pixels. Bar = 50 µm.

Vascularization Measurement on Whole Tumor Sections
Next we measured the EA on an entire neuroblastoma tumor section and compared the data obtained by scanning the section with the slide scanner to those obtained by assembling serial microscopic field pictures (montage). The data acquisition took 5 min for the scanned image and 2 hr for the montage. The tumor region analyzed contained 0.99 megapixels (39.39 mm2) in the scanned image and 42.2 megapixels (39.37 mm2) in the montage. Despite the difference of magnification between the two images, the EA measurement was similar, with 6.46% of CD31-positive area in the scanned image vs 6.21% of CD31-positive area in the montage. Therefore, the use of the slide scanner consumed less time, generated smaller files, and produced data similar to those obtained on a montage of reassembled individual microscopic fields.

Comparison of Whole Section Scanning Method with Other Methods
We then evaluated the reproducibility of the whole section scanning method and compared it to two previously reported methods, the hot spot method (Weidner et al. 1991 ) and the random fields method (Oh et al. 2001 ). Three independent observers (C.F.C., Y.A.D., G.M.) acquired images of tumor sections obtained from five individual neuroblastoma tumors by using the three different methods. EA was measured on these images with common threshold settings (one for the microscope images, one for the scanned images). The measurements and the variability for the three methods are displayed in Fig 3A and Table 1. As expected, EA values measured by the hot spot method were higher than the values obtained by the two other methods. EA values obtained by the random fields method were lower than the EA values obtained by the whole section scanning method. This observation is consistent with the fact that the selection of a limited number of random fields is not representative of the vascularization of the entire tumor section. For all three methods, the interobserver (i.e., observer-to-observer) variability was less than the tumor-to-tumor variability, and there was substantially less interobserver variability with the whole section scanning method. Similarly, the coefficient of variation, using the unexplained or experimental error variation, was less for the whole section scanning method compared to the other two methods. This resulted in a greater ratio of tumor-to-tumor variability over experimental error (sd1/sd2), suggesting a better ability of the whole section scanning method to detect differences among individual tumor samples. Another method used to evaluate the interobserver variability was to calculate the percent disagreement obtained by dividing the largest pairwise difference between observers by the average EA. The whole section scanning method again displayed the least amount of observer-to-observer variability with a percent of disagreement of 8.6% compared to 42.2% for the hot spot method and 39.0% for the random fields method. Because the neuroblastoma tumors examined had few area of necrosis, the delineation procedure was simple and consistent among observers. We therefore asked whether it would result in a higher interobserver variability when tumors with a large necrotic area were analyzed by the whole section scanning method. For this, we used sections of five individual Wnt-1 murine mammary adenocarcinomas, which typically contain highly vascularized areas adjacent to large necrotic areas (Fig 3B). The delineation procedure was standardized by eliminating necrotic areas in contact with the edge of the tumor and internal necrotic areas larger than 25% of the delineated tumor region. Small necrotic areas located inside the tumor tissue were included in the region to be analyzed. The EA measurements obtained on these more heterogeneously vascularized specimens were comparable for the three observers (Fig 3C). The interobserver variability of the EA measurement for the mammary adenocarcinoma, as determined by the percent disagreement, was 6.9%, a value similar to the 8.6% disagreement obtained with the neuroblastoma tumors. Therefore, the whole section scanning method not only constituted a time-efficient method but also was more reproducible than other methods relying on the arbitrary selection of vascular hot spots or on the random assignment of microscopic fields. With specific criteria to exclude large areas of necrosis, this method can be used for analysis of heterogeneously vascularized tumor specimens.



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Figure 3. Comparison of hot spot, random fields, and whole section scanning methods for selection of tissue area to be analyzed. (A) Three independent observers (C.F.C., Y.A.D, G.M.) measured the EA on images of tumor sections from five individual neuroblastoma tumors acquired by the three different methods. For the hot spot method, each observer measured the EA on three x20 objective field images selected in the highest vascularized area and the highest value was recorded. For the random fields method, each observer measured the EA on eight x20 objective microscopic field images randomly selected and the average of the measurements for each section was recorded. For the whole section scanning method, each observer scanned the sections and delineated the tumor region to be analyzed. The same threshold settings were used by the three observers. (B) Image of a mammary adenocarcinoma tumor acquired with the slide scanner. The delineation of the tumor region to be analyzed was standardized by eliminating necrotic areas in contact with the edge of the tumor or internal necrotic areas larger than 25% of the selected tumor region. Bar = 1 mm. (C) Each observer used the whole section scanning method to measure the EA on tumor sections from five individual mammary adenocarcinoma tumors.


 
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Table 1. Summary of variability of the three methods for neuroblastoma tumor area selectiona

Section-to-section Variability of Tumor Vascularization
To determine the variability of vascularization quantification between serial sections within the same tumor specimen, we measured the EA by the whole section scanning method in four serial sections of the same neuroblastoma tumor. The average level of EA was 6.48% (SD ± 0.48) of the entire tumor area (data not shown). The coefficient of variation calculated by dividing the standard deviation by the average EA and then multiplying by 100 was 7.46%. Therefore, the method also gave reproducible results in adjacent sections of a tumor specimen.

MVD Quantification with the Whole Section Scanning Method
Finally, we examined whether another parameter of vascularization, the microvessel density, could be quantified with the whole section scanning method. Using MetaMorph 4.6, we measured the MVD on images of an entire neuroblastoma tumor section generated by slide scanning and on a montage of serial microscopic field pictures. As for the EA measurement, the difference of magnification between the two images did not modify the MVD quantification, with 45.3 thresholded vessels/mm2 in the scanned image vs 42.3 thresholded vessels/mm2 in the montage (data not shown). Then we compared the EA and MVD values obtained with the whole section scanning method for the five individual neuroblastoma tumor sections. Although there was no significant correlation between the EA and the MVD (correlation coefficient r2=0.31; data not shown), the comparison between these parameters provided valuable information on the size of the microvessels. An example of this comparison for two neuroblastoma tumor samples (N1 and N4) with similar EA values (6.53% and 6.69%, respectively) but different MVD values (47.7 vessels/mm2 and 62.1 vessels/mm2, respectively) is shown in Fig 4. Using the MetaMorph Integrated Morphometry Analysis command as described in Materials and Methods, we measured in both tumors the total surface of each blood vessel (including the lumen) and generated for these two specimens distribution histograms according to vessel size (Fig 4A). We observed a difference in the vessel surface distribution with an increase in the number of blood vessels larger than 90 pixels and a corresponding decrease in the number of blood vessels smaller than 60 pixels in tumor N1 compared to tumor N4 (Fig 4A). Accordingly, the average vessel surface for tumor N1 (34.1 pixels) was greater than the average vessel surface for tumor N4 (25.5 pixels). Microscopic examination of these tumors confirmed the presence of several larger vessels in specimen N1 compared to specimen N4 (Fig 4B and Fig 4C). Therefore, the whole section scanning method not only provides quantitative information on EA but allows us to calculate the MVD and the average vessel surface, thus providing valuable information on the size of individual blood vessels within tumors.



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Figure 4. Comparison of the EA, the MVD, and the vessel surface of two neuroblastoma tumors (N1 and N4). (A) Using the Integrated Morphometry Analysis command of MetaMorph software, distribution histograms according to the vessel surface were generated for neuroblastoma tumors N1 and N4 with similar EA values but different MVD values. (B,C) Size of the microvessels within tumor N1 (B) and tumor N4 (C) was examined under light microscopy. Bars = 100 µm.


  Discussion
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Summary
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Materials and Methods
Results
Discussion
Literature Cited

This study describes a novel method for vascularization quantification on entire tumor sections. Charpin et al. 1995 previously reported vascularization quantification on whole tumor sections to avoid the arbitrary selection of particular fields. They measured the mean percentage of CD31 immunostained area of the counterstained area on serial microscopic field pictures obtained by automatic screening of tumor sections. The use of the slide scanner constitutes a more rapid and less expensive method to examine an entire tumor section. It generates a single image of the sample, allowing one to delineate and to easily select the relevant tumor region to be analyzed. Although this delineation remains dependent on the observer, precise instructions regarding the exclusion of necrotic area from the tumor region to be analyzed allows the generation of reproducible measurements by different observers. Consistent with a recent comparison between immunostaining quantification on low- and high-magnification images (Johansson et al. 2001 ), we showed that vascularization measurement by imaging analysis software does not require an optical magnification at acquisition time.

A potential limitation of the computerized quantification of tumor vascularization resides in the inclusion in the threshold area of nonendothelial structures that are nonspecifically stained by CD31 IHC. Such nonspecifically stained structures could be easily excluded by a trained pathologist. Anti-CD31 antibody has a high sensitivity for endothelial cell recognition but has been reported to occasionally label some plasma cells (Horak et al. 1992 ). In our frozen tumor sections, the only nonspecific DAB staining observed was due to residual peroxidase activity in highly necrotic areas. Because its intensity was weaker than the intensity of endothelial cell staining and because it was located in necrotic area excluded from the analyzed tumor region, this nonspecific staining was not included in the thresholded area actually quantified. Nevertheless, this limitation may represent a problem in tumor samples heavily infiltrated by CD31-positive nonendothelial cells, such as plasma cells, or in specimens that contain multiple areas of focal necrosis. A careful examination of the sections by a trained observer remains important before scanning and digital analysis.

The whole section scanning method was found to be highly reproducible when serial sections in the same tumor sample were examined. However, in heterogeneous tumors, it is anticipated that the analysis of nonserial sections will generate different values. Although this was not examined in this study, our method, which eliminates the need to examine several adjacent sections, allows examination of a greater number of nonadjacent sections in complex tumors in a time-efficient manner, thus increasing the ability to address tumor heterogeneity.

In this study we used the EA to quantify the tumor vascularization. Measurement of this parameter does not require the distinction of individual microvessels and may better reflect the interaction between tumor cells and peripheral blood, as previously suggested (Fox et al. 1995 ; Simpson et al. 1996 ). However, we showed that other parameters of vascularization, such as the MVD, can also be quantified by the same method using Metamorph software. Whether EA measurement is superior to MVD measurement to assess tumor vascularization is controversial in the literature (Kohlberger et al. 1996 ; Simpson et al. 1996 , Simpson et al. 1997 ). Consistent with previous reports, we found no significant correlation between the EA and the MVD. This is not unexpected because, for similar EA values, tumor samples with large blood vessels will have a lower MVD value than tumor samples with smaller blood vessels. A major advantage of the method reported here is that it allows one to obtain both EA and MVD values for each section, thus providing additional information about the size of blood vessels in tumor specimens.

In conclusion, imaging analysis software such as MetaMorph provides an objective criterion to detect and quantify immunostained microvessels in tumor tissue sections that could be applied to other immunohistochemical and histological stainings. The use of this criterion for vascularization quantification on scanned images of whole tumor section constitutes a time-efficient and reproducible method. Because it can be easily standardized, this method could also be a valuable tool for large multicenter studies in which the comparison of tumor tissues analyzed by several observers is required.


  Acknowledgments

Supported by grant CA81403 from the National Institutes of Health. C.F. Chantrain is the recipient of a Childrens Hospital Los Angeles Research Career Fellowship.

We would like to thank K. Lacina for technical assistance with immunohistochemistry and L. Blavier for providing the mammary adenocarcinoma tumor samples.

Received for publication May 6, 2002; accepted August 23, 2002.


  Literature Cited
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

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