Molecular mechanisms of antigen retrieval: antigen retrieval reverses steric interference caused by formalin-induced cross-links

Abstract

The overwhelming majority of antibodies useful for formalin fixed, paraffin embedded (FFPE) tissues require antigen retrieval to reverse the effect of formalin fixation and re-establish immunoreactivity. How this reversal happens is poorly understood. We developed a new experimental model for studying the mechanism of formalin fixation and antigen retrieval. Epitope mapping studies on nine antibodies useful for FFPE tissues revealed that each consisted of a contiguous stretch of amino acids in the native protein (linear epitope). Small peptides representing the epitopes of antibodies to human epidermal growth factor receptor type (HER2), estrogen, and progesterone receptors were attached covalently to glass microscope slides in a peptide array. Most peptides retained immunoreactivity after formalin fixation. Immunoreactivity was completely abrogated for all peptides, however, if an irrelevant large protein was present during formalin-induced cross-linking. We hypothesize that cross-linking the irrelevant protein to the peptide epitopes sterically blocked antibodies from binding. Antigen retrieval dissociates irrelevant proteins and restores immunoreactivity. Because the epitopes for clinical antibodies require only primary protein structure, the fact that antigen retrieval probably denatures the secondary and tertiary structure of the protein is irrelevant. The same mechanism may occur in tissue samples subjected to formalin fixation and antigen retrieval.     

Reversing the effects of formalin fixation with citraconic anhydride and heat: a universal antigen retrieval method.

Formalin is a commonly used fixative for tissue preservation in pathology laboratories. A major adverse effect of this fixative is the concealing of tissue antigens by protein cross-linking. To achieve a universal antigen retrieval method for immunohistochemistry under a constant condition, we developed a new method in which the effects of formalin fixation were reversed with citraconic anhydride (a reversible protein cross-linking agent) plus heating. Formalin-fixed, paraffin-embedded tissues from various organs were examined for immunohistochemical localization of a wide variety of antigens. Deparaffinized tissue sections were placed in an electric kitchen pot containing 0.05% citraconic anhydride solution, pH 7.4, and the pot was set at "keep warm" temperature mode of 98C for 45 min. This mode allowed heating the sections at a constant temperature. The sections were then washed in buffer solution and immunostained using a labeled streptavidin-biotin method using an automated stainer. In general, formalin-fixed tissues demonstrated specific immunostainings comparable to that in fresh frozen tissues and significantly more enhanced than after conventional antigen retrieval methods. In particular, even difficult-to-detect antigens such as CD4, cyclin D1, granzyme beta, bcl-6, CD25, and lambda chain revealed distinct immunostainings. Different classes of antigens such as cellular markers and receptors, as well as cytoplasmic and nuclear proteins, consistently produced enhanced reactions. This method provides efficient antigen retrieval for successful immunostaining of a wide variety of antigens under an optimized condition. It also allows standardization of immunohistochemistry for formalin-fixed tissues in pathology laboratories, eliminating inter-laboratory discrepancies in results for accurate clinical and research studies.     

Immunohistochemical detection of p53 protein in basal cell skin cancer after microwave-assisted antigen retrieval

p53 is the most frequently altered tumor-suppressor gene in skin cancer. In normal tissues the p53 protein (wild type) has a very short half-life and it is not detectable immunohistochemically. In contrast, the mutant p53 protein has an extended half-life in tumor cells and can be detected by immunohistochemical methods. p53 is widely used as an indicator of tumor aggression and progression. Fixation methods especially formaldehyde based fixation may mask the immunohistochemical detection of p53 protein but antigen retrieval methods enhance the inmmunohistochemical detection of p53 protein by remodification of protein structure. This study was designed to evaluate the efficacy of different fixatives, of microwaving and microwave pretreatment method to retrieve p53 immunoreactivity in paraffin-embedded non-lesioned (adjacent normal tissue) human skin samples or pathological human skin samples diagnosed as basal cell carcinoma. The samples were fixed at RT and/or in microwave oven either in neutral buffered formalin or alcohol for different time periods. For antigen retrieval, the sections were irradiated in a microwave oven for 5 cycles in 10 mM citrate buffer (pH 6.00). In this study the effects of six different fixation methods on the immunohistochemical staining have been investigated in basal cell tumor specimens. The application of antigen retrieval method was also examined and compared. Optimal results were obtained using samples fixed in alcohol either at room temperature (24 h) or in microwave oven.     

The Use of Mouse Models of Breast Cancer and Quantitative Image Analysis to Evaluate Hormone Receptor Antigenicity after Microwave-assisted Formalin Fixation

Microwave methods of fixation can dramatically shorten fixation times while preserving tissue structure; however, it remains unclear if adequate tissue antigenicity is preserved. To assess and validate antigenicity, robust quantitative methods and animal disease models are needed. We used two mouse mammary models of human breast cancer to evaluate microwave-assisted and standard 24-hr formalin fixation. The mouse models expressed four antigens prognostic for breast cancer outcome: estrogen receptor, progesterone receptor, Ki67, and human epidermal growth factor receptor 2. Using pathologist evaluation and novel methods of quantitative image analysis, we measured and compared the quality of antigen preservation, percentage of positive cells, and line plots of cell intensity. Visual evaluations by pathologists established that the amounts and patterns of staining were similar in tissues fixed by the different methods. The results of the quantitative image analysis provided a fine-grained evaluation, demonstrating that tissue antigenicity is preserved in tissues fixed using microwave methods. Evaluation of the results demonstrated that a 1-hr, 150-W fixation is better than a 45-min, 150-W fixation followed by a 15-min, 650-W fixation. The results demonstrated that microwave-assisted formalin fixation can standardize fixation times to 1 hr and produce immunohistochemistry that is in every way commensurate with longer conventional fixation methods.     

The effects of formalin fixation on the detection of apoptosis in human brain by in situ end-labelling of DNA

Summary The technique of DNAin situ end-labelling (ISEL) for the detection of apoptotic cells has recently become the method of choice. The incorporation of a labelled nucleotide to facilitate detection into the single-stranded region of DNA cleaved by endogenous nucleases has proved to be a sensitive and straightforward technique. Previous reports have applied the technique to the study of apoptotic cells in brain tissue, which is normally subjected to relatively long-term formalin fixation. In this study we have examined the effects of long-term formalin fixation on the ability to detect apoptosis using ISEL in a variety of pathologies and in a normal rat testis. In the tissues which had been treated with overnight formalin fixation, apoptotic cells were readily identified in those pathologies where it might be expected to occur. However, in tissue which had been fixed for several weeks or more, apoptotic cells were not detectable. Samples of brain lymphoma tissue and rat testis subjected to a prospective analysis with respect to fixation time showed that the ability to detect apoptotic cells tailed off at around 3–5 weeks. In order to obviate the risk of false negative results it would be desirable to use ISEL in tissues formalin fixed for less than this period.     

Immunohistochemical markers for quantitative studies of neurons and glia in human neocortex.

Reproducible visualization of neurons and glia in human brain is essential for quantitative studies of the cellular changes in neurological disease. However, immunohistochemistry in human brain specimens is often compromised because of prolonged fixation. To select cell lineage-specific antibodies for quantitative studies of neurons and the major types of glia, we used 29 different antibodies, different epitope retrieval methods, and different detection systems to stain tissue arrays of formalin-fixed human brain. The screening pointed at CD45/leukocyte common antigen (LCA), CD68(KP1), 2',3' cyclic nucleotide phosphatase (CNPase), glial fibrillary acidic protein (GFAP), HLA-DR, Ki67, neuronal nuclei (NeuN), p25alpha-antigen, and S100beta as candidates for future cell counting purposes, because these markers visualized specific neuronal and glial cell bodies. However, significant negative correlation between staining result and formalin fixation was observed by blinded scoring of staining for CD45/LCA, CNPase, GFAP, and NeuN in brain specimens fixed by immersion and stored up to 10 years in 4% formalin solution at room temperature, independent of donor sex and postmortem interval. In contrast, improved preservation of NeuN and CNPase staining, and full preservation of GFAP and CD45/LCA staining in tissue fixed by perfusion and stored for up to 3 years in 0.1% paraformaldehyde solution at 4C, indicated that immunohistochemistry can be performed in well-preserved biobank material.     

Combining Immunodetection with Histochemical Techniques: The Effect of Heat-induced Antigen Retrieval on Picro-Sirius Red Staining

Picro-Sirius red is a routine diagnostic stain intended for the histological visualization of collagen fibers (fibrosis) in tissue. Multi-label immunohistochemistry is a powerful tool used by researchers to visualize different cell types and their location within a tissue specimen, and to observe co-localization of antigens. Combining the specificity of immunodetection with the simplicity of Sirius red staining will allow researchers to visualize multi-antigen detection in relation to fibrosis, a common histological feature of injury in many chronic diseases. Pre-treatment of formalin-fixed, paraffin-embedded tissue (FFPE) specimens with antigen retrieval is essential for the work-up of most commercially available antibodies. The most common form of antigen retrieval involves boiling tissue specimens in buffer to break the cross-linkages caused by formalin fixation. However, this method causes tissue modification and collagen fiber shrinkage leading to suboptimal results when counterstaining for Sirius red. Reduced heat and enzymatic digestion are antigen retrieval methods compatible with Sirius red counterstaining. This paper will discuss the difficulties faced when combining these two staining methods, and provide a detailed method for the simultaneous detection of antigen and Sirius red in FFPE tissues.     

Special symposium: fixation and tissue processing models

Abstract

Fixation and processing of tissue to paraffin blocks permit thin (4-5 µm) sections of tissues to be cut. Tissues and their subcellular components and surrounding stroma are visualized by cutting thin sections and staining them histochemically or immunohistochemically and viewing the sections using a bright field microscope. During the last century, anatomists and pathologists have used fixation with 10% neutral buffered formalin (10% NBF) as the fixative of choice. Also, both human and veterinary pathologists have trained to use fixation with 10% NBF, so these professionals are reluctant to change the familiar microscopic appearance of diagnostic tissues by using different fixatives. In addition, the effects of tissue processing on the microscopic appearance of tissue essentially has been ignored in most studies. Archives of paraffin blocks of pathological tissue contain essentially paraffin blocks fixed in 10% NBF. Therefore, if retrospective studies use archival paraffin blocks to correlate the molecular features of diseases with their outcomes, the studies must be based on tissue fixed in 10% NBF. Studies of how fixation in 10% NBF interacts with histochemical and immunohistochemical staining are limited in number and most are based on relatively long fixation times (≥36 h). Currently, fixation times in 10% NBF have been reduced to <24 h. Little is known about fixation in 10% NBF and its interaction with tissue processing for any period of fixation, especially short times. Less is known about how fixation of tissues with 10% NBF interacts with more modern assays using immunohistochemistry, real time quantitative polymerise chain reaction (PCR), and techniques that depend on analysis of proteins extracted from paraffin blocks including multiplex immunoassays or mass spectrometry. In general, multiple antibody–antigen combinations are reported not to work in tissues fixed in 10% NBF, i.e., loss of immunorecognition is nearly complete for such antibody–antigen combinations as Ki67/MIB, estrogen receptor alpha (ERα) and Progesterone receptor (PR), and partial for Bcl-2. Several models have been developed to study the interactions of tissue fixation and immunorecognition, but most have viewed the problem with immunorecognition as completely caused by fixation. Also, some of the models discussed in this special symposium do not predict the effects of fixation on frozen tissues fixed in 10% NBF and not processed to paraffin blocks. This article is a brief review of issues attending the use of 10% NBF combined with tissue processing as an interrelated process to study biomarkers identified by immunohistochemistry.     

Polyester wax embedding and sectioning technique for immunohistochemistry

We have developed a method useful for immunohistochemical studies by combining tissue fixation with buffered neutral formalin and polyester wax embedding. Buffered neutral formalin fixation preserves cell and tissue fine structure, and also the antigenicity of unstable enzymes. Polyester wax embedding makes possible thin serial sections of various tissues and preserves antigenicities for at least 6 months. We have demonstrated using this technique the localization of alpha-amylase in mouse salivary gland, parietal-cell specific antigen in mouse glandular stomach, and DNA polymerase alpha and beta in chick tissue.     

Optimization of immunohistochemical techniques to detect extracellular matrix proteins in fixed skin specimens

Complete antigen visualization in the context of well-preserved tissue architecture is the goal of all immunohistochemical techniques. Frozen tissue section techniques achieve optimal antigen visualization but preserve tissue architecture poorly. On the other hand, formalin-fixed tissue section techniques preserve tissue architecture very well but result in antigen masking. Enzymatic digestion or salt extraction of formalin-fixed sections has been used to reestablish antigen expression. Recently acid-alcohol-fixed tissue has been used as a successful compromise between tissue architecture preservation and the visualization of cytoskeletal antigens. In an attempt to find an improved immunohistochemical process for non-cytoskeletal antigens, we compared avidin-biotin immunofluorescence staining in frozen, formalin-fixed, and acid-alcohol-fixed tissues. The fixed tissues were either untreated or treated with enzyme digestion or salt extraction. For this study, we examined healing cutaneous wounds in Yorkshire pigs with antibodies to fibronectin, laminin, von Willebrand factor VIII, and keratin. Although tissue architecture was poor, frozen sections provided the best antigen visualization and were therefore used as the standard for complete antigen expression. Formalin-fixed tissues had excellent tissue architecture, but most antigens were completely masked. Pre-treatment technique only partially overcame the antigen masking caused by formalin. In contrast, acid-alcohol fixation preserved tissue architecture almost as well as formalin and sometimes allowed complete antigen visualization; however, laminin and fibronectin were partially masked. Total recovery of the expression of these antigens could be obtained by pre-treating the acid-alcohol-fixed tissue with either hyaluronidase or 1 M NaCl. Therefore, acid-alcohol-fixed tissue appears best for extracellular matrix (ECM) protein immunostaining as well as for cytoskeletal staining. However, certain ECM antigens require hyaluronidase or 1 M NaCl treatment for optimal visualization.     

Effects of Prolonged Formalin Fixation on Diagnostic Immunohistochemistry in Domestic Animals

Immunohistochemistry (IHC) is routinely used in diagnostic pathology to detect infectious agents, to immunophenotype neoplastic cells, and to prognosticate neoplastic diseases. Formalin fixation is considered a limiting factor for IHC because formalin can cross-link antigens and mask epitopes. Prolonged formalin fixation is presumed to result in decreased antigen detection; however, this effect has only been evaluated with a few antibodies. The goal of this study was to evaluate the effect of prolonged formalin fixation on the immunohistochemical detection of 61 different antigens. Approximately 5-mm-thick tissue slices were fixed in 10% neutral-buffered formalin. Tissue slices were removed from formalin, processed, and paraffin-embedded at 1-day, 3-day, and then at ∼1-week intervals. IHC was performed on all sections in tandem after all tissues were processed. Immunoreactions were evaluated by three pathologists according to a four-tier grading system. Immunoreactivity of cytokeratin 7, high-molecular-weight cytokeratin, and laminin was diminished by prolonged formalin fixation. However, immunohistochemical reactivity remained moderate to strong with up to 7 weeks of fixation for all other antibodies. These results suggest that prolonged formalin fixation has minimal effects on antigen detection for most commonly used antibodies. These results further validate the use of IHC in diagnostic pathology. (J Histochem Cytochem 57:753–761, 2009)     

Effects of fixation time and enzymatic digestion on immunohistochemical demonstration of bromodeoxyuridine in formalin-fixed, paraffin-embedded tissue

We studied the effects of fixation time and enzymatic digestion on immunohistochemical staining for bromodeoxyuridine (BUdR) in excised rat and human gastrointestinal tissues and human brain tumors which had been fixed in formalin after intravenous administration of BUdR shortly before biopsy of tissue. In formalin-fixed rat gastrointestinal tissues not treated with proteinase, the reaction products were insufficient to identify BUdR-positive cells. Results similar to those in ethanol-fixed tissue were obtained when formalin-fixed tissue sections were treated with protease, pepsin, or trypsin. The longer the material had been fixed in formalin, the longer the incubation in proteinase required to identify BUdR-labeled nuclei. The BUdR labeling indices of formalin-fixed human brain tumor specimens treated with protease were comparable to those of ethanol-fixed tissues. Sufficient BUdR staining was obtained even in tissues fixed in formalin for prolonged periods. Therefore, the BUdR labeling index can be determined retrospectively in clinical materials stored in formalin.     

Commercial Formalin Substitutes for Histopathology

We compared the performance of six commercial fixatives proposed to be formalin substitutes with the performance of buffered formalin, Clarke's ethanol-acetic acid, and ethanol, using rat liver, small intestine, and kidney. We investigated the rate of penetration, mode of fixation, extent of protein and structural immobilization, quality of histology and cellular structure following routine dehydration and paraffin embedding, and performance as a fixative for immunohistochemistry. Furthermore, we evaluated the effects of the various fixatives on ultrastructure. Only buffered formalin performed equally well on all tissues tested. While several of the commercial fixatives appeared to preserve liver tissue at 200, the preservation of kidney, intestinal villi, and smooth muscle was unacceptable. Histological distortion, cell shrinkage and vacuolization were prominent when the substitutes or ethanol were used. In contrast, these artifacts were found occasionally and to a minor degree when buffered formalin or Clarke's fixative were used. Immunohistochemistry demonstrated a total loss of low molecular weight antigen (serotonin) and patchy reactions for high molecular weight antigens for all fixatives except buffered formalin. The best immunostaining was obtained by combining formalin fixation with antigen retrieval. We conclude that none of the proposed commercial substitutes for buffered formalin are adequate for critical histology or histopathology.     

Differential sensitivity of the microtubule-associated protein, tau, in Alzheimer's disease tissue to formalin fixation

Immunohistochemistry of formalin-fixed human Alzheimer's disease (AD) tissue using an anti-tau antibody (Tau-1) reveals staining of neurofibrillary tangles (NFTs) and neuritic plaques (NPs), whereas normal axonal staining is less apparent. In this study, we used a combined biochemical and histochemical approach to assess effects of formalin on immunoreactivity of AD tau. Nitrocellulose blots were treated with fixative to mimic conditions used with tissue sections, a method that might be generally useful for assessing antigen sensitivity to different fixatives. A progressive decrease in Tau-1 immunoreactivity of the tau bands on a Western blot was observed with increasing times of formalin fixation. Phosphatase-digested blots demonstrated an increase in Tau-1 immunoreactivity compared to control blots. These results mimic the phosphatase-sensitive Tau-1 immunohistochemical staining of formalin-fixed AD tissue slices previously reported. Fixation of AD tissue with periodate-lysine-paraformaldehyde (PLP) preserves axonal tau antigenicity. Phosphatase digestion of PLP-fixed AD tissue enhances Tau-1 immunoreactivity of NFTs and NPs but does not alter axonal staining. These results indicate that axonal form(s) of tau are more sensitive to formalin fixation than pathology-associated tau. In addition, a modification of AD tau in pathological structures may protect it from the effects of formalin with regard to Tau-1 antigenicity.     

Microwave oven-based technique for immunofluorescent staining of paraffin-embedded tissues

Immunohistochemical analysis of formalin-fixed paraffin-embedded tissues can be challenging due to potential modifications of protein structure by exposure to formalin. Heat-induced antigen retrieval techniques can reverse reactions between formalin and proteins that block antibody recognition. Interactions between antibodies and antigens are further enhanced by microwave irradiation, which has simplified immunohistochemical staining protocols. In this report, we modify a technique for antigen retrieval and immunofluorescent staining of formalin-fixed paraffin-embedded tissues by showing that it works well with several antibodies and buffers. This microwave-assisted method for antigen retrieval and immunofluorescent staining eliminates the need for blocking reagents and extended washes, which greatly simplifies the protocol allowing one to complete the analysis in less than 3 h.     

PAXgene fixation enables comprehensive metabolomic and proteomic analyses of tissue specimens by MALDI MSI

An alcohol-based non-crosslinking tissue fixative, PAXgene Tissue System, has been proposed as alternative fixation method to formalin, providing superior and morphological preservation. To date, metabolites have not been assessed in PAXgene-fixed tissues. The study focuses on a comparison between PAXgene and standard formalin fixation for metabolomic analysis by MALDI mass spectrometry imaging. Therefore, fifty-six samples from seven mice organs were fixed with PAXgene (PFPE) or formalin (FFPE), embedded in paraffin, and processed to a tissue microarray. PAXgene was able to spatially preserve metabolites in organs achieving an overlap of common metabolites ranging from 34 to 78% with FFPE. Highly similar signal intensities and visualization of molecules demonstrated negligible differences for metabolite imaging on PFPE compared to FFPE tissues. In addition, we performed proteomic analysis of intact proteins and peptides derived from enzymatic digestion. An overlap of 33 to 58% was found between FFPE and PFPE tissue samples in peptide analysis with a higher number of PFPE-specific peaks. Analysis of intact proteins achieved an overlap in the range of 0 to 28% owing to the poor detectability of cross-linked proteins in formalin-fixed tissues. Furthermore, metabolite and peptide profiles obtained from PFPE tissues were able to correctly classify organs independent of the fixation method, whereas a distinction of organs by protein profiles was only achieved by PAXgene fixation. Finally, we applied MALDI MSI to human biopsies by sequentially analyzing metabolites and peptides within the same tissue section. Concerning prospective studies, PAXgene can be used as an alternative fixative for multi-omic tissue analysis.     

Leaching of Trace Elements from Biological Tissue by Formalin Fixation

In studies of trace elements in biological tissue, it is imperative that sample handling does not substantially change element concentrations. In many cases, fresh tissue is not available for study, but formalin-fixed tissue is. Formalin fixation has the potential to leach elements from the tissue, but few studies have been published in this area. The concentrations of 19 elements were determined by high-resolution inductively coupled plasma mass spectrometry in formalin in which human and rat brain samples had been stored for different time durations ranging from weeks up to several years. Additional analysis was carried out in fixed brain samples. There was substantial leaching of elements from the tissue into the formalin, and the leaching varied considerably between different elements. For example, formalin concentrations of As, Cd, Mg, Rb, and Sb increased more than 100-fold upon long-term (years) storage, while for Ni and Cr, the leaching was negligible. The degree of leaching was strongly time-dependent. In conclusion, formalin fixation and storage of biological tissue has the potential to leach substantial fractions of several trace elements from the tissue. The potential of leaching must be critically considered when using formalin-fixed biological tissue in trace metal analysis.     

Heat pretreatment increases resolution in DNA flow cytometry of paraffin-embedded tumor tissue

BACKGROUND: Flow cytometry of single-cell suspensions prepared by enzymatic digestion from formalin-fixed, paraffin-embedded tissue suffers from several major drawbacks. The most important factors that influence the results are the high and unpredictable coefficients of variation (CVs) of the G0/G1 peak in the DNA histogram and reduction of propidium iodide (PI) intercalation with DNA, resulting from protein cross-linking by formalin. METHODS: In this study we introduce a heating step (2 h incubation in citrate solution at 80 degrees C) prior to a brief pepsin digestion of tissue sections in the protocol for DNA content analysis of formalin-fixed and paraffin-embedded tissue. This new method is compared with established methods for the preparation of cell suspensions from frozen and paraffin-embedded tissues with respect to cell yield, DNA histogram resolution, DNA dye saturation kinetics, cell cycle parameters, and antigen retrieval in various epithelial and nonepithelial tissues. RESULTS: The recovery of single cells from the paraffin sections was doubled by the heat treatment step, while the limited time of proteolysis resulted in decreased cell debris. Furthermore, an increased fraction of cells became cytokeratin-positive, while these immunocytochemically stained cells also exhibited a higher mean fluorescence intensity. The DNA histograms prepared from cell suspensions obtained according to this new protocol showed a significantly improved resolution, leading to a better identification of peridiploid cell populations. Heat pretreatment of paraffin-embedded archival tissue sections showed PI saturation kinetics similar to, or even better than, those of fresh unfixed tissues, independent of duration of fixation. CONCLUSIONS: This new method, making use of routinely available antigen retrieval principles, thus allows high-resolution DNA analysis of routinely fixed and paraffin-embedded tissue samples. Using external reference cells, inter- and intralaboratory standardization of DNA histograms can be achieved.     

Immunohistochemical detection of the inducible heat shock protein hsp70: a methodological study.

Stress-inducible Hsp70i and constitutively expressed Hsc70 are highly related heat shock proteins. Aberrant expression levels and intracellular localization of these proteins has been suggested as a potential marker in certain tumors. The aim of our study was to work out a reliable, immunohistochemical detection of the stress-inducible Hsp70i protein and enabling discrimination between Hsp70i and Hsc70 proteins in paraffin-embedded human tissues. We tested the effect of several fixative procedures and antigen retrieval on the effectiveness of the Hsp70i detection in murine cells cultured in vitro and in liver of rats subjected to heat shock. For cells grown in vitro, specific Hsp70i immunoreactivity was obtained with all fixatives used. However, samples fixed in 10% formalin and 4% paraformaldehyde required antigen retrieval. In liver tissue embedded in paraffin, regardless the fixative used, positive Hsp70i staining could be visible only if antigen retrieval was applied. We applied this procedure for detection of Hsp70i in routine sections of breast and lung cancers fixed with 10% formalin and found that the application of thermal antigen retrieval significantly enhanced the SPA810 immunoreactivity and reduced background staining. This procedure enabled also the differential detection of Hsp70i and Hsc70 in routine histopathological preparations.