The use of glutaraldehyde and tannic acid to preserve reconstituted collagen for electron microscopy

The effects of glutaraldehyde and tannic acid on the axial periodicity of collagen have measured. Both fixatives produce axial shrinkage of the collagen but whereas glutaraldehyde produces 7% shrinkage, tannic acid produces only 2% shrinkage. The technique of carbon/platinum shadowing was used to estimate the extent to which the collagen fibrils flatten down when they are dried onto grids for electron microscopy without prior embedding and sectioning. The influence of fixation was studied and it was found that minimum distortion occurred when both tannic acid and glutaraldehyde were used to preserve the protein structure.     

Ultrastructural visualization of elastic fibres with a tannate-metal salt method

Summary A modification of the tannic acid-metal salt method was applied as an ultrastructural stain for elastin. Thin sections of glutaraldehyde-fixed, embedded rat aorta and rabbit elastic cartilage, with and without osmication, were examined. Raising the pH of the tannic acid solution from 2.7 to 9.0 progressively increased the electron-density of elastic fibres and collagen fibrils in osmicated and unosmicated specimens. The maximum tannic acid staining of elastic fibres was observed in the pH range 7.0–9.0. Collagen staining, although less intense than that of elastic fibres, was also greatest in this pH range. Elastic fibres in osmicated specimens demonstrated the strongest tannic acid staining with a minimal increase in density of collagen and cell nuclei when compared to the unosmicated specimens. Sequential treatments of osmicated specimens with tannic acid pH 7.0–9.0, and uranyl acetate, pH 4.1, enhanced the density of the elastin intensely, increased collagen staining moderately, but hardly increased the density of nuclei and microfibrils. In elastase-digested osmicated specimens, all tannic acid (pH 7.0)-uranyl acetate-reactive elastin was selectively removed. These results demonstrate that all the neutral and alkaline tannic acid-uranyl acetate methods can be used as a postembedment stain for elastin specimens fixed in glutaraldehyde and osmium tetroxide.     

The Use of Tannic Acid-Glutaraldehyde in the Study of Elastic and Elastic-Related Fibers

Fixation with tannic acid—glutaraldehyde permits distinction of oxytalan, elaunin and elastic fibers in the electron microscope. The results obtained using tannic acid at concentrations of 1.0%, 0.5% and 0.25% in 3% glutaraldehyde were compared. The 0.25% concentration is recommended for studying fine details of connective fibrils and for regular staining of elastin.     

Glutaraldehyde-induced changes in the axially projected fine structure of collagen fibrils

The fine structure of the collagen fibril, as seen in axial projection, is changed by treatment with glutaraldehyde. The changes are detectable in electron-optical staining patterns and in the intensities of the low-angle meridional X-ray diffraction maxima. Current knowledge of the amino acid sequence of collagen and of the axial arrangement of molecules in fibrils permits interpretation in terms of specific alterations to the axial distribution of electron density along the fibril. Analysis of fibril staining patterns from glutaraldehyde-treated calf skin collagen shows that uptake of staining ions in positive staining patterns is inhibited at residues known to interact with glutaraldehyde (lysyl, hydroxylysyl and probably histidyl side-chains) and on other charged residues in the immediate neighbourhood of the glutaraldehyde-reactive residues. This can be seen as a "stain-exclusion effect" due to the presence of bulky polymeric complexes of glutaraldehyde molecules at cross-linking sites. Such stain exclusion accounts for the drastic changes in the negative staining pattern following treatment with glutaraldehyde. The intensity changes observed in the low-angle meridional X-ray reflections from rat tail tendon, similarly treated, also can be explained by the presence of these bulky complexes. Existing data have been used to predict a model of the altered electron density profile indicating the axial distribution of glutaraldehyde along a D-period of moist tendon collagen.     

Laminated figures of the intercisternal regions of dictyosome-like structures from guinea-pig spermatocytes fixed with glutaraldehyde-tannic acid

Dictyosome-like structures (DLS) of guinea pig spermatocytes, when prefixed in mixtures of glutaraldehyde and tannic acid, exhibited laminated figures with a repeating periodicity of about 4.5 nm in the spaces between DLS saccules or in association with the surfaces of the DLS saccules. These laminated figures were similar to those figures derived from saturated lipids in other tissues. Alternatively, spaces between saccules were collapsed leaving only thin, electron-dense material separating adjacent saccules. These changes were not observed when the DLS were prefixed in glutaraldehyde before exposure to tannic acid. The presence of laminated figures following fixation with tannic acid and osmium tetroxide suggests that saturated lipids are present in, or associated with, the intersaccular regions of the DLS. The distribution of laminated figures in other membrane structures was not affected by post fixation with tannic acid nor were laminated figures comparable to those of the DLS observed between cisternae of the Golgi apparatus. These results support previous conclusions that DLS are distinct from Golgi apparatus and are a unique component of the germ cell cytoplasm.     

Microtubules in myelinated and unmyelinated axons of rat sciatic nerve

Summary Tannic acid in glutaraldehyde was used to stain microtubules in myelinated and unmyelinated axons of rat sciatic nerve. In the majority of areas the tannic acid failed to penetrate the unmyelinated axons whilst penetrating neighbouring myelinated axons, suggesting a difference in the ability of the two types of nerves to exclude tannic acid. Where tannic acid had penetrated the unmyelinated axons the 13 protofilament substructure and size of the microtubules appeared identical to those seen in the myelinated axons.     

Production of gallic acid by immobilization of Rhizopus oryzae

Production of gallic acid using the immobilized cells of Rhizopus oryzae has been studied. It was observed that 2% tannic acid concentration, 200 numbers of calcium alginate beads of spore concentration 2?×?10⁵/ml and initial pH 5.0 gave the maximum gallic acid production. The % of tannin conversion was 78.5% whereas in free cell culture, the % conversion was 83.5% in 4 days of incubation period. The beads were used for 3 times successfully. A drastic fall in the hydrolysis process was observed when the beads were treated with glutaraldehyde.     

Dual effect of tannic acid on the preservation and ultrastructure of phosphatidyl choline vesicles

Summary The use of tannic acid has been proposed to improve the preservation of phospholipids in tissues. We investigated the effects of tannic acid on the preservation of small unilamellar vesicles, prepared from sonicated aqueous suspensions of phospholipids.With cryo-electron microscopy it is demonstrated that small unilamellar vesicles are formed after sonication of the phospholipid suspensions. Fixation of vesicles without tannic acid results in extraction of the phospholipids during dehydration and embedding. Fixation of vesicles containing phosphatidyl choline with tannic acid, with or without glutaraldehyde, results in a fast (within a second) aggregation of the vesicles and the resulting sediment can be dehydrated and embedded when a postfixation in osmium tetroxide is carried out. Small unilamellar vesicles fixed in this way are retrieved in thin sections as multilamellar vesicles with a periodicity of about 5 nm for dimyristoylphosphatidyl choline and about 6 nm for dioleoylphosphatidyl choline.By using ¹³C-phosphatidyl choline it was also demonstrated that tannic acid prevents to a large extend the extraction of phosphatidyl choline during fixation, dehydration and embedding. This dual effect of tannic acid on phosphatidyl choline, aggregation and fixation, should be considered when using tannic acid in tissue preparation.     

Tannic acid improves the visualization of the human erythrocyte membrane skeleton by freeze-etching

The effect of fixatives on the membrane skeleton underlying the human erythrocyte membrane was examined by freeze-etching. An anastomosing fibrillar network was readily observed on the protoplasmic surface of the erythrocyte membrane treated with tannic acid. Such structure was much less defined in unfixed membrane or membrane fixed with glutaraldehyde or glutaraldehyde followed by osmium tetraoxide. Tannic acid caused a marked increase in diameter of the fibrillar components of the membrane skeleton and of the protoplasmic surface particles of inside-out vesicles prepared by alkali treatment but did not affect the size of intramembranous particles seen on fracture faces nor the appearance of exoplasmic surfaces. The improved visualization of the membrane skeleton after treatment with tannic acid resulted from interactions between tannic acid and exposed membrane proteins.     

Tannic acid as a stabilizer of liposomal lipids in electron microscopic research

Using electron microscopy the action of tannic acid on the morphology of positively charged liposomes were studied in suspension and after adsorption of the surface membrane of human red blood cell in vitro. After treatment with tannic acid and glutaraldehyde followed by postosmication, an irreversible reconstruction of liposome lipid material with formation of many layers with tight packed lamellae was shown. Similar structures were found on the surface of red blood cells. Monolayer microvesicles 30 nm in diameter were seen after glutaraldehyde fixation postosmication, and final treatment with tannic acid. Similar microvesicles were seen adsorbed on the plasma membrane.     

Staining of the elastic fibers in insect connective tissue after tannic acid/glutaraldehyde fixation.

Locust neural lamella and Calpodes connective tissue fixed in glutaraldehyde have a fibrous component which stains after reaction with DAB and osmication and after staining sections with PTA. The fibers also stain when fixed in glutaraldehyde with tannic acid followed by osmication and section staining with lead citrate.     

中草药提取物中单宁(鞣质)的选择性脱除

用牛皮为原料通过甲醛交联反应制备胶原纤维吸附材料,采用外加单宁的方法研究了这种吸附材料对双黄莲口服液、银黄注射液及中草药提取物中单宁的选择性吸附能力。结果表明,胶原纤维对单宁具有明显的竞争吸附能力和吸附选择性,在实验条件下单宁的去除率达到97％以上,而对有效成份吸附率很低。皮胶原纤维吸附材料为中药制剂工艺中单宁的高选择性脱除提供了一种新的、有效的方法。     

Quantitative analysis of chondroitin sulphate retention by tannic acid during preparation of specimens for electron microscopy

Summary The ability of tannic acid to enhance binding of glycosaminoglycans to purified collagen was analysed in an in vitro system using amino sugar analysis on an amino acid analyser, transmission electron microscopy, and scanning electron microscopy. Collagen was purified by digestion with trypsin, papain, and hyaluronidase. Purified collagen was incubated with hyaluronic acid or with chondroitin sulphate glycosaminoglycan and then treated with tannic acid. Tannic acid was found to enhance retention during preparation for electron microscopy of either of the glycosaminoglycans onto collagen fibres. The ability of tannic acid to enhance binding of collagen and glycosaminoglycans might explain, at least in part, its structural reinforcement effect on resected synovial joint-apposing surfaces during preparation for scanning electron microscopy.     

Size changes in single muscle fibers during fixation and embedding.

During fixation of single muscles fibers with glutaraldehyde, the volume of the fiber shrinks 20%, recovers in rinse and osmium tetroxide to near normal volume and shrinks 20% again when staining with uranyl acetate. This suggest that osmotic properties of membranes may not have been completely lost during fixation, post-fixation and en bloc staining. Dehydration in ethanol and propylene oxide produces a further 10% shrinkage in volume. Infiltration and embedding with Epon causes an additional 15% change in volume. This gives a total shrinkage in volume of 45% which is nearly twice that of the apparent shrinkage in the volume of the myosin lattice as determined by electron microscopy.     

Preparation and characterization of a thermostable and biodegradable biopolymers using natural cross-linker

The present study describes preparation and characterization of a thermally stable and biodegradable biopolymer using collagen and a natural polymer, alginic acid (AA). Required concentration of alginic acid and collagen was optimized and the resulting biopolymer was characterized for, degree of cross-linking, mechanical strength, thermal stability, biocompatibility (toxicity) and biodegradability. Results reveal, the degree of cross-linking of alginic acid (at 1.5% concentration) with collagen was calculated as 75%, whereas it was 83% with standard cross-linking agent, glutaraldehyde (at 1.5% concentration). The AA cross-linked biopolymer was stable up to 245°C and Exhibits 5-6-fold increase in mechanical (tensile) strength compared to plain collagen (native) materials. However, glutaraldehyde cross-linked material exhibits comparatively less thermal stability and brittle in nature (low tensile strength). With regard to cell toxicity, no cytotoxicity was observed for AA cross-linked material when tested with mesenchymal cells and found degradable when treated with collagenase enzyme. The nature of bonding pattern and the reason for thermal stability of AA cross-linked collagen biopolymer was discussed in detail with the help of bioinformatics. A supplementary file on efficacy of AACC as a wound dressing material is demonstrated in detail with animal model studies.     

Microfibrils in the myotendon junctions.

Myotendon junctions in the rectus abdominis muscles of bull frogs were examined by the fixation combination of tannic acid and glutaraldehyde using electron microscopy. The features observed on myotendon junctions were the following: (1) There were many deep invaginations of muscle cell membrane at the end of the muscle fibers. Terminal thin filaments of myofibrils were attached to the electron-dense layer lining under the muscle cell membrane on the lateral walls of invaginations. (2) The basement membrane covering the muscle cell membrane was thicker in the invaginations than on the other sites of muscle fibers. (3) Collagen fibers in the invaginations gradually tapered off toward the bottom of the invaginations. But it was not seen that the collagen fibers were attached to both the basement membrane and cell membrane of muscle cells. (4) On the observations using the tannic acid-glutaraldehyde fixation, it was clearly seen that the microfibrils extend from the outer leaflets of the cell membrane to the collagen fibers in invaginations via the basement membrane. It was concluded that the myofibrils might be fastened to the collagen fibers of the tendon by the intermediates of the microfibrils.     

The use of tannic acid for the ultrastructural visualization of hyaluronic acid

Summary This study describes a method, which makes use of tannic acid (2%) as a component of a paraformaldehyde-glutaraldehyde based fixative, to reveal the presence and ultrastructure of glycosaminoglycans in the extracellular matrix. The ultrastructure of the extracellular matrix in the stage 24 chick embryo wing is examined after fixation by several procedures. After fixation in the absence of tannic acid, the intercellular spaces contain little extracellular matrix, except for occasional fibrils (collagen?). On the other hand, when tannic acid is included in the primary fixative, the intercellular spaces contain considerable amounts extracellular matrix which includes 3±0.5 nm filaments, ±30 nm granules, as well as putative collagen fibrils. The 3±0.5 nm diameter fibrils are not observed when the limbs had been injected in ovo with Streptomyces hyaluronidase (specific for hyaluronic acid) prior to fixation. Furthermore, the 3±0.5 nm fibrils resemble authentic hyaluronic acid that had been fixed by the same procedure in the presence of tannic acid. Limbs treated with tannic acid after osmication contained only small amounts of extracellular material, which was confined largely to cell surfaces. These results demonstrate that the use of tannic acid in the primary fixative can serve as a useful method for the ultrastructural visualization of several extracellular matrix materials, including hyaluronic acid.This study was supported by NIH grant HD 05505     

Tannic Acid Supplemented Fixation Improves Ultrastructural Evaluation of Respiratory Epithelium in Children with Recurrent Respiratory Tract Infections

Samples of the respiratory mucosa of children with recurrent respiratory infections suspected of having primary ciliary dyskinesia are routinely fixed with glutaraldehyde before ultrastructural examination. This standard technique, however, may not be optimal for visualizing ciliary components or for preserving several cellular and extracellular structures during dehydration and embedding procedures. In this study, brushes of nasal (28 samples) and/or tracheal (9 samples) mucosa from 32 children with recurrent respiratory tract infections were examined. Twenty-nine samples were fixed with glutaraldehyde supplemented with tannic acid to determine if the ultrastructural analysis of respiratory epithelium and bronchial secretions could be improved. Eight samples were conventionally fixed with glutaraldehyde alone. Lesions of the cellular membrane and damaged cells were easily visualized using tannic acid supplemented fixation. Internal ciliary structures including individual microtubules and dynein arms were also more clearly observed. In addition, the internal structure of microvilli of the respiratory epithelium could be studied and the presence of phospholipid-rich surfactant-like material within nasal and tracheal secretions were visualized after tannic acid supplemented fixation. We suggest that addition of tannic acid during fixation is useful for accurate ultrastructural evaluation of respiratory mucosa in both clinical and experimental situations.     

Unfixed tissue for electron immunocytochemistry: a simple preparation method for colloidal gold localization of sensitive epitopes using ethanediol dehydration

Summary A quick, simple protocol is described for the preparation of tissue for electron immunocytochemistry without the use of fixatives or deleterious solvents. Fresh, normal human colon was rapidly dehydrated in ethanediol (ethylene glycol) then embedded directly in low-acid glycol methacrylate. Using both mono-and polyclonal antibodies, in conjunction with colloidal gold probes, a range of intra-and extracellular epitopes were localized; these epitopes included lysozyme, chromogranin, desmin and collagen IV. Overall, the tissue compared well with material fixed in glutaraldehyde, partially dehydrated and embedded in LR White acrylic resin. Ultrastructural detail was good and was further enhanced, without affecting probe density and epitope localization, by the addition of 1% tannic acid or 1% uranyl acetate to the dehydrant. The technique is applicable to a wide range of tissues, allowing excellent antigen retention which might prove useful for the immunolocalization of sensitive epitopes.     

蛋白质,纤维素和单宁酸对东方田鼠摄食的影响

食物选择性是动物对取食生境中现存的食物种类做出的选择,是一个复杂的生态适应过程,与动物自身生理状及环境中食物的可利用量密切相关。单宁酸、蛋白质和纤维素是影响植食性动物食物选择的重要因素。在控制其它营养因子的条件下,设置10%蛋白质+2.25%纤维素+3%单宁酸(食物1)/6%单宁酸(食物2)和20%蛋白质+4.51%纤维素+3%单宁酸(食物3)/6%单宁酸(食物4)4个处理组,通过自助餐式选择笼内的喂养实验,测定单宁酸、蛋白质和纤维素对东方田鼠食物选择的影响。结果表明,东方田鼠对3%单宁酸处理组食物摄食量显著高于对6%单宁酸处理组(P0.001);但东方田鼠对6%单宁酸食物摄食量依蛋白质浓度变化,在20%蛋白质处理组的摄食量显著高于10%蛋白质处理组(P0.05);在含3%单宁酸处理组中,纤维素成为影响东方田鼠摄食的主要因素,而当单宁酸浓度增加到6%时,纤维素和蛋白质对东方田鼠摄食影响差异不显著;总之,单宁酸、蛋白质和纤维素对东方田鼠的摄食都产生重要影响,单宁酸对东方田鼠食物选择的影响程度最大,纤维素次之,蛋白质对东方田鼠摄食的影响会随单宁酸浓度的升高而增大。