Aldehyde pararosanilin (true aldehyde fuchsin) stains purified insulin, oxidized or not, following adequate fixation with either formalin or Bouin's fluid

Gomori reported that aldehyde fuchsin stained the granules of pancreatic islet beta cells selectively and without need of permanganate pretreatment. Others adopted permanganate oxidation because it makes staining faster though much less selective. All aldehyde fuchsins are not equivalent, being made from "basic fuchsin" whose composition may vary from pure pararosanilin to one of its methylated homologs, rosanilin or a mixture. Mowry et al. have shown that only aldehyde fuchsin made from pararosanilin stained unoxidized pancreatic beta cells (PBC). Aldehyde fuchsins made from methylated homologs of pararosanilin stain PBC cells only after oxidation, which induces basophilia of other cells as well; these are less selective for PBC. Is the staining of PBC by aldehyde fuchsins due to insulin? Others have been unable to stain pure insulin with aldehyde fuchsins except in polyacrylamide gels and only after oxidation with permanganate. They have concluded that insulin contributed to the staining of oxidized but not of unoxidized PBC. This view denies any inherent validity of the more selective staining of unoxidized PBC cells as an indication of their insulin content. We describe here indisputable staining of unoxidized pure insulins by aldehyde fuchsin made with pararosanilin. Dried spots of insulin dissolved in the stain unless fixed beforehand. Spots of dried insulin solution made on various support media and fixed in warm formalin vapor were colored strongly by the stain. Insulin soaked Gelfoam sponges were dried, fixed in formalin vapor and processed into paraffin. In unoxidized paraffin sections, presumed insulin inside gel spaces was stained strongly by aldehyde pararosanilin. Finally, the renal tubules of unoxidized paraffin sections of kidneys from insulin-injected mice fixed in either Bouin's fluid or formalin were loaded with material stained deeply by aldehyde pararosanilin. This material was absent in renal tubules of mice receiving no insulin. The material in the spaces of insulin-soaked gels and in the renal tubules of insulin-injected mice was proven to be insulin by specific immunostaining of duplicate sections. The same material was also stained by aldehyde pararosanilin used after permanganate. So, this dye stains oxidized or unoxidized insulin if fixed adequately.     

Aldehyde Pararosanilin (True Aldehyde Fuchsin) Stains Purified Insulin, Oxidized or Not, Following Adequate Fixation with Either Formalin or Bouin'S Fluid

Gomori reported that aldehyde fuchsin stained the granules of pancreatic islet beta cells selectively and without need of permanganate pretreatment. Others adopted permanganate oxidation because it makes staining faster though much less selective. All aldehyde fuchsins are not equivalent, being made from “basic fuchsin” whose composition may vary from pure pararosanilin to one of its methylated homologs, rosanilin or a mixture. Mowry et al. have shown that only aldehyde fuchsin made from pararosanilin stained unoxidized pancreatic beta cells (PBC). Aldehyde fuchsins made from methylated homologs of pararosanilin stain PBC cells only after oxidation, which induces basophilia of other cells as well; these are less selective for PBC.

Is the staining of PBC by aldehyde fuchsins due to insulin? Others have been unable to stain pure insulin with aldehyde fuchsins except in polyacrylamide gels and only after oxidation with permanganate. They have concluded that insulin contributed to the staining of oxidized but not of unoxidized PBC. This view denies any inherent validity of the more selective staining of unoxidized PBC cells as an indication of their insulin content.

We describe here indisputable staining of unoxidized pure insulins by aldehyde fuchsin made with pararosanilin. Dried spots of insulin dissolved in the stain unless fixed beforehand. Spots of dried insulin solution made on various support media and fixed in warm formalin vapor were colored strongly by the stain. Insulin soaked Gelfoam® sponges were dried, fixed in formalin vapor and processed into paraffin. In unoxidized paraffin sections, presumed insulin inside gel spaces was stained strongly by aldehyde pararosanilin. Finally, the renal tubules of unoxidized paraffin sections of kidneys from insulin-injected mice fixed in either Bouin's fluid or formalin were loaded with material stained deeply by aldehyde pararosanilin. This material was absent in renal tubules of mice receiving no insulin. The material in the spaces of insulin-soaked gels and in the renal tubules of insulin-injected mice was proven to be insulin by specific immunostaining of duplicate sections. The same material was also stained by aldehyde pararosanilin used after permanganate. So, this dye stains oxidized or unoxidized insulin if fixed adequately.     

Only aldehyde fuchsin made from pararosanilin stains pancreatic B cell granules and elastic fibers in unoxidized microsections: problems caused by mislabelling of certain basic fuchsins

The most distinctive property of aldehyde fuchsin is its staining of certain nonionic proteins and peptides in unoxidized cells and tissues. These substances include granules of pancreatic islet B cells, elastic fibers and hepatitis B surface antigen. Aldehyde fuchsin made from two different basic fuchsins, each certified by the Biological Stain Commission and labelled C.I. (Colour Index) No. 42500 (pararosanilin), did not stain pancreatic B cells at all. Stain Commission's records and retesting showed that each of the "faulty" basic fuchsins was not pararosanilin, but rosanilin, whose Colour Index number is 42510. These basic fuchsins were labelled with the wrong Colour Index number when packaged. Additional basic fuchsins were coded by V.M.E. and tested by R.W.M. for their capacity to make satisfactory aldehyde fuchsins. Only certain of these aldehyde fuchsins stained unoxidized pancreatic islet B cells. The same aldehyde fuchsins stained elastic fibers strongly. Each basic fuchsin whose aldehyde fuchsin was judged satisfactory proved to be pararosanilin. Aldehyde fuchsin solutions made from other basic fuchsins stained elastic fibers only weakly and did not stain pancreatic B cells at all in unoxidized sections. Each basic fuchsin whose aldehyde fuchsin was unsatisfactory proved to be rosanilin. It appears that only aldehyde fuchsin made from pararosanilin stains unoxidized pancreatic B cell granules dependably. We found that basic fuchsins from additional lots of Commission-certified pararosanilin and rosanilin were also labelled with incorrect Colour Index numbers when packaged. Steps were taken to prevent recurrences of such mislabelling which has made it difficult until now to correlate differences in the properties of pararosanilin and rosanilin. A table is provided of all basic fuchsins that have been certified by the Biological Stain Commission since 1963 when they began the practice of subdesignating basic fuchsins according to whether they are pararosanilins or nonpararosanilins. The consumer can readily determine from the certification number on the label the correct subdesignation of any Commission-certified basic fuchsin listed here. Until now, mislabelling of some lots of pararosanilin as rosanilin and vice-versa has confused and frustrated the users of basic fuchsins in other applications such as the carbol fuchsin staining of tubercle bacilli and certain cytochemical tests, e.g. esterase and acid phosphatase, that utilize hexazotized pararosanilin as a coupling reagent. Consumers experiencing trouble with any Commission-certified dye should look to the Biological Stain Commission for help. This is an important reason for purchasing, whenever possible, only Biological Stain Commission certified dyes.     

Effects of fuchsin variants in aldehyde fuchsin staining

Aldehyde fuchsin stains pancreatic B cell granules, hypophyseal basophils, goblet cell mucins, gastric chief cells, hyaline cartilage, and elastica. Neither the chemical structure of aldehyde fuchsin nor its staining mechanism is known. This study was undertaken to clarify the role of the fuchsin component of aldehyde fuchsin in its staining reaction. The major findings of this investigation include: 1) single N-methylation of the fuchsin molecule abolishes staining of unoxidized pancreatic B cells, although it does not prevent reaction of fuchsin with paraldehyde; 2) aldehyde fuchsin is probably a Schiff base condensation product of pararosaniline and acetaldehyde; 3) a Schiff base structure alone cannot account for aldehyde fuchsin staining of unoxidized pancreatic B cells; 4) a fully potent aldehyde fuchsin is possibly a Tris-Schiff base derivative of pararosaniline.     

The role of paraldehyde in the rapid preparation of aldehyde fuchsin

Preparation of aldehyde fuchsin normally requires ripening for 3 to 5 days. By using a 5-fold excess of paraldehyde a fully potent aldehyde fuchsin can be prepared in 24 hr at room temperature. Aldehyde fuchsin prepared by both normal and accelerated ripening afforded comparable results, including selective staining of unoxidized pancreatic B cells. Dried aldehyde fuchsin prepared form pararosaniline and reconstituted in acid alcohol has spectrophotometric properties different form the ripened strain. Reconstituted aldehyde fuchsin stains unoxidized B cells adequately only if staining time is extended. Excess paraldehyde added to reconstituted aldehyde fuchsin retards decomposition but does not produce a normal stain by spectrophotometric standards. Warming of aldehyde fuchsin solutions to accelerate ripening has been shown to produce deleterious effects and should be avoided.     

Specificity and Sensitivity of Insulin Staining by Aldehyde Fuchsin, Pseudoisocyanin and Toluidine Blue

Aldehyde fuchsin, pseudoisocyanin and toluidine blue, histochemical dyes reported to be specific for insulin-containing granules of the pancreatic beta cell, were applied to insulin fixed in polyacrylamide gel by disc electrophoresis. Two major and four minor bands were resolved as demonstrated by staining with amidoschwarz; only the two major bands, were stained by aldehyde fuchsin. The addition of serum did not affect this reaction. Serum or insulin components gave no metachromatic reactions to the other stains. Under the conditions applied, aldehyde fuchsin is the only one of these dyes specific for insulin in this, system, but this stain is not sufficiently sensitive to detect normal serum levels of the hormone.     

Staining properties of aldehyde fuchsin analogs.

This investigation was designed to clarify the role of the aldehyde component of aldehyde fuchsin in its staining reactions. Several aldehyde fuchsin analogs were prepared by using different aldehydes. The staining quality of these analogs and pararosaniline-HCl was compared with that of aldehyde fuchsin prepared with paraldehyde in the usual way. The major findings of this investigation include: 1) Aldehyde fuchsin staining of nonoxidized pancreatic B cells requires a stain prepared with either paraldehyde or acetaldehyde. 2) An aldehyde moiety is required for aldehyde fuchsin staining of strong tissue anions. 3) Staining of elastic tissue with aldehyde fuchsin analogs resembles staining of strong tissue anions more than staining of nonoxidized pancreatic B cells. Possible reaction mechanisms of aldehyde fuchsin with tissue substrates are discussed.     

A histochemical investigation of the mechanism of Aldehyde Fuchsin staining of pancreatic B-cell granules

Summary The reaction mechanism by which Aldehyde Fuchsin selectively stains pancreatic B-cell granules is unknown. The participation of either insulin or proinsulin in the reaction is debatable; the stain may be bound by other components of the B-cell granule or its membrane. Sections of pancreas were stained with a variety of basic stains and specific histochemical reagents with and without appropriate blocking agents. No evidence for strong tissue anions associated with the B-cell granule could be found. Aldehyde Fuchsin staining was not abolished by lowering the pH below the point at which all known tissue anions should be protonated. There was no evidence that the Aldehyde Fuchsin staining solution itself generates reactive groups in the tissue. The results of this investigation support a non-ionic, possibly covalent mechanism for Aldehyde Fuchsin staining of pancreatic B-cell granules.     

Aldehyde fuchsin staining, direct or after oxidation: problems and remedies, with special reference to human pancreatic B cells, pituitaries, and elastic fibers.

Successful production of aldehyde fuchsin (AF) having the unique properties described by Gomori depends on each of many critical variables. AF made from basic fuchsins which contain mainly rosanilin (C.I. 42510) do not stain properly-fixed pancreatic B cells, pituitary basophils, or elastic fibers in unoxidized sections. AF made from basic fuchsins containing mainly pararosanilin (C.I. 42500) stains these entities strongly. Substances stained by AF without oxidation fall into two classes: 1) nonacidic peptides and proteins, most of which contain half-cystines, and 2) polyanions, particularly when sulfated. Group 2 substances stain rapidly, Group 1 substances stain slowly. Many modifications of aldehyde fuchsin have been described. Modified aldehyde fuchsins (MAFs) differ in the kind of aldehyde and in the amount of aldehyde and hydrochloric acid used in their formulation; they differ also in the temperature and duration of the ripening necessary before they can be used. If microsections are first oxidized by acid permanganate or other oxidant, MAF staining of pancreatic B cells, pituitary basophils and other substances containing cystines is speeded and intensified. Most modified methods prescribe oxidation, but the author's does not. The chemical basis, final result and potential side-reactions of oxidation methods (OXMAF) differ from those of direct methods (DIMAF) such as the author's. DIMAF staining is slower but inherently simpler and less destructive. The time required for optimal staining with DIMAF depends on the potency of the stain, which in turn depends on how the stain was made and its age. Detection of DIMAF--reactive peptides and proteins may be hampered by the strong staining of polyanions. This can be remedied if the polyanions are first stained with Alcian blue (AB) or other durable basic dye of contrasting color resistant to acid ethanol. Experiences with the AB-DIMAF staining of pancreatic B cells, pituitaries and elastic fibers in formalin-fixed human tissues are detailed. Proper control of the variables which affect MAF will insure useful and reliable results either directly or after oxidation. Authors and editors are urged to be more careful hereafter to distinguish the results of DIMAF from those of OXMAF methods. Published reports should always specify the parameters that affect the properties of MAF. In OXMAF methods the steps intervening between oxidation and staining should be spelled out. Such care should help dispel the confusion and uncertainty which cloud the use and reputation of aldehyde fuchsin at present. This unique dye deserves wider and wiser use.     

Keratin in the Egg Shells of Amphistomes; Histochemical Differentiation from Quinonetanned Protein in Other Trematoda

Various combinations of the oxidation method for demonstrating keratin in shell material of amphistomes were tried. Acidified permanganate worked more efficiently than performic and peracetic acids, and Alcian blue and aldehyde fuchsin excelled other basic dyes for subsequent staining. For the permanganate-Alcian blue reaction, sections of material fixed in Susa or Bouin were oxidized in 0.3% permanganate in 0.3% H₂SO₄ for 5 min., decolourized in 1% oxalic acid, stained in 3% Alcian blue in 2 N H₂SO₄ and counterstained with eosin. The shell globules stained a deep blue. For permanganate aldehyde fuchsin staining, the sections were stained in aldehyde fuchsin for 1 hr, after oxidation with permanganate. The shell globules then stained a deep magenta. The catechol and fast red reactions were negative in amphistomes and the specimens lack the characteristic amber colour due to quinone tanning.     

The demonstration of two acid groups in juxtaglomerular granules with basic triphenyl methane dyes,aldehyde-fuchsin and schiff's reagent

Summary Oxidation and bromination of mouse kidney JG cell-granules result in the production of cysteic acid from cystine; cysteic acid is capable of taking up rapidly and selectively certain basic triphenyl methane dyes including aldehyde fuchsin at lower pH levels.After treatment with periodic acid, bromine and hydrochloric acid, the JG granules or the nuclear chromatin also take up the basic triphenyl methane dyes (including aldehyde fuchsin) which contain amino groups, probable as a result of the production of aldehyde groups. Basic triphenyl methane lacking amino groups does not react with aldehydes.Some substance present in JG granules could be stained by aldehyde fuchsin after prior oxidation; HCl methyl violet 2B was taken up both with or without prior oxidation. Only strong methylation completely abolished these affinities which were restored after demethylation. These reactions are attributed to cystine.The staining of JG granules with dilute aldehyde fuchsin and dilute methyl violet 2B is not affected by oxidation, bromination, aldehyde blocking and hydrolysis; these reactions are abolished by mild methylation, but restored by subsequent saponification. These staining properties are due to the presence of carboxylic acid in JG granules.The positive PAS reaction of JG granules is due to the presence of 1.2-glycol in the same granules.     

Aldehyde-fuchsin: historical and chemical considerations.

The staining mechanisms of Gomori's aldehyde-fuchsin are not yet fully understood. It seemed therefore timely to review the history of this dye class in context with current dye and aldehyde chemistry. In 1861 Lauth treated basic fuchsin with acetaldehyde. This dye became known as Aldehyde Blue, but consisted of violet and blue dyes. Schiff (1866) studied several aldehyde-fuchsins; these compounds contained two molecules of dye and three molecules of aldehyde. Acetaldehyde-fuchsin prepared according to Schiff's directions showed staining properties similar to those of Gomori's aldehyde-fuchsin. This dye class was soon superseded by new dyes more suitable for textile dyeing, and chemical investigations of aldehyde-fuchsins ceased around the turn of the century. Gomori's aldehyde-fuchsin has been regarded as a Schiff base. However, according to chemical data, low molecular aliphatic aldehydes and aromatic amines tend to form condensation products. Correlations of chemical and histochemical observations suggest such processes during aging of dye solutions. Models of dimers and polymers of aldehyde-fuchsin could be built without steric hindrance. The nature of the bonds formed by various components of aldehyde-fuchsin solutions is not clear. However, cystine in proteins, e.g. in basement membranes, apparently does not play a role in the binding of aldehyde-fuchsin by unoxidized Carnoy- or methacarn-fixed sections.     

Concentric Layers in the Granules of Human Nervous Lipofuscin Demonstrated by Silver Impregnation

Representative pieces of human brain were fixed in 10% formalin, embedded in paraffin and sectioned at 5 μ. Paired sections were used, one of which was oxidized in equal parts of 0.5% potassium permanganate and 0.5% sulfuric acid for 1-2 min, while the other was left unoxidized. Both the oxidized and unoxidized sections were impregnated with silver diamine. The lipofuscin granules in the nerve cells appeared as small intensely stained black dots, surrounded by a clear unstained zone, in the unoxidized sections, while in the oxidized sections there was an outer ring of intensely blackened material surrounding a central unstained dot.     

Aldehyde-fuchsin: Historical and chemical considerations

Summary The staining mechanisms of Gomori's aldehyde-fuchsin are not yet fully understood. It seemed therefore timely to review the history of this dye class in context with current dye and aldehyde chemistry. In 1861 Lauth treated basic fuchsin with acetaldehyde. This dye became known as Aldehyde Blue, but consisted of violet and blue dyes. Schiff (1866) studied several aldehyde-fuchsins; these compounds contained two molecules of dye and three molecules of aldehyde. Acetaldehyde-fuchsin prepared according to Schiff's directions showed staining properties similar to those of Gomori's aldehyde-fuchsin. This dye class was soon superseded by new dyes more suitable for textile dyeing, and chemical investigations of aldehyde-fuchsins ceased around the turn of the century. Gomori's aldehyde-fuchsin has been regarded as a Schiff base. However, according to chemical data, low molecular aliphatic aldehydes and aromatic amines tend to form condensation products. Correlations of chemical and histochemical observations suggest such processes during aging of dye solutions. Models of dimers and polymers of aldehyde-fuchsin could be built without steric hindrance. The nature of the bonds formed by various components of aldehyde-fuchsin solutions is not clear. However, cystine in proteins, e.g. in basement membranes, apparently does not play a role in the binding of aldehyde-fuchsin by unoxidized Carnoy- or methacarn-fixed sections.     

Staining Mast Cells for Morphometric Evaluation on an Image Analysis System

Multiple skin sections from three nonhuman primates (Macaca mulatta) and three hairless guinea pigs (Cavia porcellus) were stained with 12 different histologic stains to determine whether mast cells could be selectively stained for morphometric analysis using an image analysis system (IAS). Sections were first evaluated with routine light microscopy for mast cell granule staining and the intensity of background staining. Methylene blue-basic fuchsin and Unna's method for mast cells (polychrome methylene blue with differentiation in glycerin-ether) stained mast cell granules more intensely than background in both species. Toluidine blue-stained sections in the guinea pig yielded similar results. Staining of the nuclei of dermal connective tissue was enhanced with the methylene blue-basic fuchsin and toluidine blue stains. These two stains, along with the Unna's stain, were further evaluated on an IAS with and without various interference filters (400.5-700.5 nm wavelengths). In both the methylene blue-basic fuchsin and toluidine blue stained sections, mast cell granules and other cell nuclei were detected together by the IAS. The use of interference filters with these two stains did not distinguish mast cell granules from stained nuclei. Unna's stain was the best of the 12 stains evaluated because mast cell granule staining was strong and background staining was faint. This contrast was further enhanced by interference filters (500.5-539.5 nm) and allowed morphometric measurements of mast cells to be taken on the IAS without background interference.     

The intragranular location of carboxyl groups in neuromelanin and lipofuscin in human brain and in meningeal melanosomes in mouse brain

The intragranular location of carboxyl groups was tinctorially determined in human substantia nigra neuromelanin granules, human inferior olive lipofuscin granules, and mouse meningeal melanosomes. Soluble and insoluble lipid was stained with beta naphthol Sudans in unoxidized and oxidized frozen and paraffin sections containing neuromelanin or lipofuscin. Nile blue demonstrated carboxyls in unoxidized neuromelanin, lipofuscin, and melanin, and in oxidized neuromelanin and lipofuscin. Carbodiimide demonstrated carboxyls in unoxidized and oxidized lipofuscin and oxidized neuromelanin. In all instances, staining for carboxyls was inhibited by prior mild methylation, and proof of their presence was obtained by a pre-staining, stepwise, alternating, and repetitive mild demethylation, mild methylation sequence. Structurally, carboxyls were demonstrated in the neuromelanin granule's soluble lipid-free lipofuscin component, in the meningeal melanosome's melanin component, and virtually throughout the lipofuscin granule. The following structural and chemical basis was proposed for the different resistance of Nile blue staining of melanosomes and of neuromelanin and lipofuscin to acetone extraction. Nile blue forms an insoluble complex with melanosomal dopa-melanin's quinonoid, diphenolic, and undissociated carboxyl units. Such complex formation does not occur in neuromelanin's carboxyl-free dopamine-melanin component, however. Instead, Nile blue ionogenicly bonds with dissociated carboxyls belonging to the neuromelanin granule's lipofuscin component.     

A Staining Sequence for A, B and D Cells of Pancreatic Islets

Recent investigations strongly suggest the elaboration of a third pancreatic hormone by the D cell and the existence of cells which show the staining properties of both B and D cells. Demonstration of these and all other islet cells in a single section is possible by the following staining sequence: (1) of D cells by silver or toluidine blue, (2) of B cells by pseudoisocyanin, and (3) empirical staining of all islet cells together by aldehyde fuchsin, ponceau de xylidine, acid fuchsin and light green. Difficulties in embedding compact pancreatic tissue can be overcome by dehydrating to 80% ethanol, followed by tetrahydrofurane as the intermediate fluid to paraffin infiltration.     

Silver impregnation of Alzheimer's neurofibrillary changes counterstained for basophilic material and lipofuscin pigment

A method is described in which selective silver staining of Alzheimer's neurofibrillary changes is combined with staining of cell nuclei, Nissl material, and lipofuscin granules. Formalin fixed, paraffin embedded sections of human autopsy tissue are silver stained according to a method proposed by Gallyas. Lipofuscin is stained by crotonaldehyde fuchsin following performic acid oxidation. Nissl substance is visualized by either Darrow red or gallocyanin-chrome alum staining. Architectonic units showing the specific pathology and the neuronal types prone to develop the neurofibrillary changes can be recognized using this technique.     

Silver Impregnation of Alzheimer's Neurofibrillary Changes Counterstained for Basophilic Material and Lipofuscin Pigment

A method is described in which selective silver staining of Alzheimer's neurofibrillary changes is combined with staining of cell nuclei, Nissl material, and lipofuscin granules. Formalin fixed, paraffin embedded sections of human autopsy tissue are silver stained according to a method proposed by Gallyas. Lipofuscin is stained by crotonaldehyde fuchsin following performic acid oxidation. Nissl substance is visualized by either Darrow red or gallocyanin-chrome alum staining. Architectonic units showing the specific pathology and the neuronal types prone to develop the neurofibrillary changes can be recognized using this technique.     

Morphological changes of pancreatic B cells in ventromedial hypothalamic (VMH)-lesioned obese rats

Morphological changes of pancreatic B cells were investigated in ventromedial hypothalamic (VMH)-lesioned obese rats. An increase in body weight, a decrease in body length, and a marked increase in fat-pad were observed in VMH-lesioned obese rats. The volume density of pancreatic islets and that of B cells in VMH-lesioned obese rats were more increased than those in sham-operated control rats. The B cells of VMH-lesioned obese rats often showed a slight reaction for aldehyde fuchsin or anti-pig insulin serum. By the electron microscopy, the degranulated B cells were found to contain well developed Golgi apparatus and rough endoplasmic reticulum. These observations indicate increased activities of synthesis and release of insulin. We concluded that VMH-lesioned obesity was caused by accelerated lipogenesis with hypersecretion of insulin.