In this third study on the fluorescence overlay antigen mapping (FOAM) technique, we have addressed the question of which differences of antigen distributions close to the resolving power of the light microscope can be distinguished. An answer to this question should provide clues to future applications of the technique aiming at the topographic differentiation of IgG deposits displayed at the epidermal basement membrane zone (EBMZ) in certain bullous skin disorders. For the present purpose we have developed a topographicStainingmodel~human~,uSingsauctutalEBMz antigens as topographic reference markers. The distribution of these markers relative to one another is visualized in FOAM images obtained by selective double immunofluorescence tracing and videomicroscopic overlay imaging. The theoretical resolution limit of the technique is discussed and
To identify in tissue sections the relative positions of antigen distributions close to the resolving power of the microscope, we have developed the fluorescence overlay antigen mapping (FOAM) procedure. As this technique makes high demands on the geometric fidelity of the overlay image, it is essential to recognize geometric errors resulting from optical imperfections. This applies in particular to the image shift difference (ISD) that may routinely occur during fluorescence overlay. We describe here procedures for assessment and mechanical correction of the ISD in tissue sections. Furthermore, we describe an alignment verification test to assess the accuracy of the ISD correction procedure, using collagen Type VII as the geometric verification marker. These procedures should enable reliable evaluation of relative antigen distributions in tissue sections using photomicrographic multicolor fluorescence overlay. Further details of the FOAM technique, such as color fidelity and its utility for diagnostic and research purposes, will be published separately.
In this third study on the fluorescence overlay antigen mapping (FOAM) technique, we have addressed the question of which differences of antigen distributions close to the resolving power of the light microscope can be distinguished. An answer to this question should provide clues to future applications of the technique aiming at the topographic differentiation of IgG deposits displayed at the epidermal basement membrane zone (EBMZ) in certain bullous skin disorders. For the present purpose we have developed a topographic staining model in human skin, using structural EBMZ antigens as topographic reference markers. The distribution of these markers relative to one another is visualized in FOAM images obtained by selective double immunofluorescence tracing and videomicroscopic overlay imaging. The theoretical resolution limit of the technique is discussed and suggests an effective lower limit of some 60-65 nm. Although this limit is not reached under present conditions, our results show that it is possible to distinguish topographic differences of antigen distributions with an upper resolution limit of 200 +/- 50 nm. Furthermore, our findings indicate that collagen Type VII and beta 4 integrin are the most suitable molecules to serve as topographic reference markers in future applications of the technique aiming at the differentiation of bullous pemphigoid (BP) and epidermolysis bullosa acquisita (EBA). Preliminary results on this topic are most promising indeed.
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