Dichromate-Chlorate Perfusion Prior to Staining Degeneration in Brain and Spinal Cord

A method of fixation compatible with both the Nauta-Gygax and Swank-Davenport procedures for degenerating nerve fibers, which shortens the time required by the former procedure, is as follows: The central nervous system is perfused with a 0.9% aqueous solution of NaCl followed by an aqueous solution containing 5% K₂Cr₂O₇ and 2.5% KClO₃. The central nervous system is then hardened in 10% formalin for 1-3 days. Tissue for Marchi-type staining can be taken at this stage. For silver staining, the processing is continued by immersion overnight in 10% formalin in 20% alcohol, and frozen sections cut the next day. Sections, up to 50μ in thickness, are collected in 10% formalin and impregnated by the Nauta-Gygax technique. Best results are obtained by impregnating within 24-48 hr after sectioning.     

Adaptation of the Nauta Method for Use on Degenerating Fibers in Rat Cortex and Thalamus

Lesions produced in the cerebral cortex of rats were studied by Nauta's method for degeneration. The brains were perfused with physiological NaCl solution, followed by 10% neutral (CaCO₃) formalin. The brains were removed and stored in the formalin for 2 wk to 1 yr. Experimental modifications of the staining method showed that its sensitivity for fine degenerating fibers could he enhanced by the following changes: (a) omitting 0.05% potassium permanganate; (b) replacing the hydroquinone-oxalic acid mixture with 0.1% pyrogallol. Procedure: (1) frozen sections to water; (2) 0.5% phosphomolybdic acid, 45 min; (3) distilled water, 1 min; (4) 0.1% pyrogallol (aq.), 2 min; (5) distilled water, 3 washes of 1 min each; (6) 1.5% silver nitrate (aq.), 30 min; (7) distilled water, 1 min, (8) Laidlaw's ammoniated silver carbonate, 10110 sec; (9) Nauta's reducer, 1-2 min; (10) distilled water, 1 min; (11) 1.0% Na₂S₂O₃, 2 min; (12) distilled water 3 changes, 1 min each; (13) dehydrate, clear, and cover. This method gave equally good results on degenerating axons in both cortex and thalamus.     

Laboratory Hints from the Literature: A Department Devoted To Abstracts Of Books and Papers From Other Joubnals Dealing With Stains and Microscopic Technic In General

Lesions produced in the cerebral cortex of rats were studied by Nauta's method for degeneration. The brains were perfused with physiological NaCl solution, followed by 10% neutral (CaCO₃) formalin. The brains were removed and stored in the formalin for 2 wk to 1 yr. Experimental modifications of the staining method showed that its sensitivity for fine degenerating fibers could he enhanced by the following changes: (a) omitting 0.05% potassium permanganate; (b) replacing the hydroquinone-oxalic acid mixture with 0.1% pyrogallol. Procedure: (1) frozen sections to water; (2) 0.5% phosphomolybdic acid, 45 min; (3) distilled water, 1 min; (4) 0.1% pyrogallol (aq.), 2 min; (5) distilled water, 3 washes of 1 min each; (6) 1.5% silver nitrate (aq.), 30 min; (7) distilled water, 1 min, (8) Laidlaw's ammoniated silver carbonate, 10110 sec; (9) Nauta's reducer, 1-2 min; (10) distilled water, 1 min; (11) 1.0% Na₂S₂O₃, 2 min; (12) distilled water 3 changes, 1 min each; (13) dehydrate, clear, and cover. This method gave equally good results on degenerating axons in both cortex and thalamus.     

Structural bases of sensomotor integration in the cat's cerebral cortex

Connections of the somatosensory cortex surrounding the postcruciate fossa with the lateral region of the motor area (in the cruciate sulcus) were established by the Nauta-Gygax and Fink-Heimer methods and also by the retrograde horse-radish peroxidase transport method. A high degree of differentiation was found in the organization of transcortical sensomotor projections. The pyramidal, stellate, and inverted pyramidal neurons in the third layer of the cortex were shown to take part in the formation of these pathways. Results obtained by the experimental degeneration method combined with electron microscopy showed that afferentation from the first somatosensory area of the cortex reaches mainly cells in layers III and V. It is suggested that the influence of the association fibers on projection neurons in the motor area is transmitted either directly or through interneurons.M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 13, No. 5, pp. 460–466, September–October, 1981.     

Efferent connections of the striatum in Tupinambis nigropunctatus

The striatum of the lizard Tupinambis nigropunctatus lies in the lateral wall of the telencephalon and consists of two major subdivisions: the dorsal striatum and the ventral striatum. Electrolytic lesions were placed in all parts of the striatal complex and in adjacent areas and the subsequent anterograde degeneration was studied using the Nauta-Gygax and Fink-Heimer techniques. Lesions in the dorsal striatum cause terminal degeneration in the ventral striatum both ipsi- and contralaterally. In addition, projections have been found to the lateral amygdaloid nucleus and to parts of the dorsal striatum not affected by the lesion. Following lesions in the ventral striatum fiber degeneration could always be observed in the ventral peduncle of the lateral forebrain bundle. Corresponding terminal degeneration was found in the anterior and posterior entopeduncular nuclei, the tegmentum mesencephali, the substantia nigra, the prerubral area, the mesencephalic central grey and the lateral cerebellar nucleus. When the large celled part of the ventral striatum was involved in the lesion additional degeneration could be traced to the nucleus rotundus via the dorsal peduncle of the lateral forebrain bundle.     

Toluidine Blue-Alizarin Red S Staining of Cartilage and Bone in Whole-Mount Skeletons in Vitro

Cartilage and bone of the developing skeleton can be reliably differentiated in whole-mount preparations with toluidine blue-alizarin red S staining after FAA fixation. The recommended staining procedure is based chiefly on the use of newborn white and Swiss-Webster mice, 4-9 days postnatal, but was tested also on mice and rats 3-8 wk of age. Procedure: Sacrifice, skin, eviscerate, remove body fat, and place specimens in FAA (formalin, 1; acetic acid, 1; 70% alcohol, 8) for approximately 40 min. Stain in 0.06% toluidine blue made in 70% ethyl alcohol for 48 hr at room temperature. Use 20 volumes of stain solution to the estimated volume of the specimen. Destain soft tissues in 35% ethyl alcohol, 20 hr; 50%, 28 hr; and 70%, 8 hr. Counterstain in a freshly prepared 1% aqueous solution of KOH to which is added 2-3 drops of 0.1% alizarin red S per 100 ml of solution. Each day for 3 days, transfer the specimen to a fresh 1% KOH-alizarin mixture, or until the bones have reached the desired intensity of red and soft tissues have cleared. Rinse in water, and place in a 1:1 mixture of glycerol and ethyl alcohol for 1-2 hr, then transfer the specimen to fresh glycerol-alcohol for final clearing and storage. Older mice and rats require procedural modifications: (1) fixation for 2 hr, (2) 0.12% toluidine blue, (3) maceration for 4 days in 3% KOH-alizarin, and (4) preliminary clearing for 24 hr in a mixture of glycerol, 2; 70% ethyl alcohol, 2; and benzyl alcohol, 1 (v/v) before placing in a 1:1 alcohol-glycerol mixture.     

Cocaine, in contrast to D-amphetamine, does not cause axonal terminal degeneration in neostriatum and agranular frontal cortex of Long-Evans rats

Continuous three day administration via implanted minipumps of cocaine hydrochloride (50-450 mg/kg/day, sc and 100-250 mg/kg/day, iv) did not produce axonal degeneration in frontal agranular cortex or neostriatum that was detectable by Fink-Heimer silver staining or tyrosine hydroxylase immunolabeling. This is in contrast to the extensive axonal degeneration detectable in these regions following d-amphetamine sulfate (10-60 mg/kg/day) administered following an identical protocol. Doses of cocaine and amphetamine were equated using three measures: 1) weight loss, 2) lethality and 3) behavioral activation. Thus, cocaine resembles other catecholamine reuptake blockers and does not cause the neurodegenerative changes characteristic of other abused drugs that interact with the brain's dopamine systems.     

Rapid Schedules for Koh Clearing and Alizarin Red S Staining of Fetal Rat Bone

Various schedules for staining fetal rat skeleton with alizarin red S were tested to determine a procedure that would produce a completely cleared and well-stained specimen in a short period of time. A 2 day procedure is presented which can produce specimens that are satisfactory but not completely transparent. A 7 day procedure produces cleared and stained specimens which can be well visualized with a dissecting microscope (30×). Fetal rats of 21 days gestation were fixed in 10% formalin for at least 1 wk. The specimens were skinned and eviscerated and then dehydrated in 2 changes of acetone for 12 hr (8 ml per gram body weight). The specimens were then placed in 1% KOM-alizarin red S (6 mg/liter) or 3 days, followed by 10% KOH-alizarin red S for 3 days. Finally, the specimens were placed in a mixture of benzyl alcohol, ethanol, and glycerol (1:2:2) (4 ml per gram body weight) for 12 hr, and then transferred to pure glycerol for storage.     

Seedling recruitment on agriculturally improved mesic grassland: the influence of disturbance and management schemes

Question: Are the recruitment patterns of deliberately introduced wildflower species influenced by cutting frequencies and disturbance treatments? To what extent do these different treatments affect productivity and sward structure of an agriculturally improved grassland? Location: A mesic lowland grassland near Göttingen, Lower Saxony, Germany. Methods: Recruitment success of eight sown wildflower species was studied in a permanent grassland treated by a factorial combination of different pre‐sowing cutting intervals (1, 3 or 9 wk), post‐sowing cutting intervals (1,3 or 9 wk) and disturbance (control, harrowing, removal of sward). Seedling emergence and survival, biomass production and sward structure were followed over two years. Results: For most species seedling emergence was highest in the harrowing treatment. The complete sward removal did not further increase seedling emergence. Seedling survival was strongly influenced by the post‐sowing cutting frequency with highest mortality in the 9 wk cutting interval compared to one and 3 wk cutting intervals. Annual dry matter yield varied between 4.4, 5.9 and 9.4 t.ha^‐1 in the 1,3 and 9 wk pre‐sowing cutting treatment, respectively. In June, when the seeds were sown, the tiller number of the 1 wk cut plots was twice as high as for the 9 wk cut plots and five times higher than in the harrowing treatment. Conclusions: Disturbance by harrowing provided the optimal environmental cues to trigger germination, whereas seedling survival was facilitated by increased light penetration due to frequent cutting. The investigation revealed the overriding importance of frequent standing crop removal in the early phase of seedling establishment on agriculturally improved grassland.     

A Six-Dye Staining Schedule for Sections of Mesquite and Other Desert Plants

Materials are fixed in FPA (formalin, 2; propionic acid, 1; 70% ethanol, 17). Paraffin sections on slides are brought to 50% ethanol and stained as follows: (1) in Bismarck brown Y, a 0.02% solution in 0.1% aqueous phenol, 10-30 min; wash 30 sec in 0.7% acetic acid, and wash in distilled water 20-30 sec; (2) in crystal violet, 1% in 70% ethanol alkalinized with 1 drop of 1 N NaOH per 100 ml, 12-35 min; wash 30-60 sec in tap water to remove excess stain, and rinse 0.5 sec in 70% ethanol; then mordant in I₂-KI, 1% each in 70% ethanol, 40 sec, and rinse in 70% ethanol 2-5 sec; (3) in a mixture containing 0.4% acid fuchsin and 0.6% crythrosin B in 70% ethanol about 0.5 sec; rinse in 70% ethanol 5-15 sec to remove excess red; dehydrate in 70%, 95%, and absolute ethanol, 2-3 sec each; (4) in fast green FCF, 0.5% in a mixture of equal parts of methyl cellosolve, absolute ethanol, and clove oil, 5-15 sec; rinse in a mixture of clove oil, 10 ml; absolute ethanol, 100 ml; and methyl cellosolve, 10 ml, 5-7 sec; (5) in orange G, 0.75 gm in a mixture of clove oil, 40 ml; absolute ethanol, 40 ml; and methyl cellosolve, 60 ml, 5-30 sec; rinse clean in a 1:1 mixture of xylene and absolute ethanol, 5-20 sec Complete the clearing in pure xylene, 3 changes, 1.5 min in each, and apply a cover glass with synthetic resin. Slides are agitated in all steps except Bismark brown Y, crystal violet, and the xylenes. Contrast and staining intensity are adjusted by varying staining times in the dye solutions.     

Marchi's Staining Method: Studies of Some of the Underlying Mechanisms Involved

Spinal cord of cat and rabbit was stained, after experimental lesions, by variations of Marchi's method. The following conclusions were drawn:

1. The presence of an oxidizing agent (K₂Cr₂O₇, NaIO₃, or KCIO₃) in the osmic acid solution is of primary importance and a preliminary oxidation in Mueller's fluid is unnecessary or even detrimental.

2. Acetic acid added to Marchi's fluid, accentuates the action of the oxidizing agent in restraining the staining of normal myelin.

3. Too high concentration of oxidizing agent or of acid may inhibit staining of degenerating myelin.

4. Marchi's and Busch's methods have been modified as follows: Fix one day in 10% formalin and transfer without washing to the staining mixture, either A or B. Staining mixture A: Marchi's fluid plus 1 to 3% glacial acetic acid. B: An aqueous solution containing KCIO₃ 0.25%, osmic acid 0.33%, and acetic acid 1%. Stain about one week. These methods worked on spinal cord and medulla, but cannot be recommended for brain.

5. The detrimental effects of long post mortem autolysis or of prolonged fixation in formalin may be counteracted to some degree by increasing the concentration of the acid in Marchi's fluid up to 5% or of the KCIO₃ up to 0.4% in the modified Busch's fluid.     

Methyl Green-Pyronin for Staining Autoradiographs of Hydroxyethyl Methacrylate-Embedded Lymphoid Tissue

Cells in the spleen in DNA-synthesis were labelled with tritiated thymidine. Tissue was fixed for 12 hr in 10% neutral formalin, washed for 4 hr in tap water and dehydrated through 70% and absolute ethanol. The tissue blocks were infiltrated overnight with a mixture consisting of glycol methacrylate, 80 ml; polyethylene glycol 400, 12 ml; and benzoyl peroxide, 0.27 gm. Specimens were cast in BEEM capsules with the final embedding medium consisting of 42 parts of the infiltration medium and 1 part of an acceleration mixture. This mixture consisted of N,N-dimethylaniline, 1 part and polyethylene glycol 400, 15 parts. The blocks hardened in 30 min and were sectioned with an ultramicrotome fitted with glass knives. Sections were coated with Ilford K5 liquid emulsion and exposed for 2 wk. Methyl green-pyronin staining of autoradiographs was carried out at pH 4.1 in acetate buffer containing 0.5% methyl green (Allied Chemicals) and 0.2% pyronin GS (Chroma). Staining was for 30-60 min, after which sections were washed for 1 min in water, blotted, allowed to dry, and mounted in Canada balsm. The procedure resulted in good quality autoradiographs in which the degree of basophilia of labelled cells could be assessed.     

Modification of the Marchi Technic

The formula proposed by Swank and Davenport (1935) was modified and applied to human and macaque nervous material. Three groups of experiments were performed and the following observations were made. (1) Diluting the osmic acid component, without altering the relative concentration of the other constituents of the solution resulted in practically no staining of the degenerated fibers. (2) When all constituents of the staining solution were used in much lower concentration than previously suggested, enhancement of staining of the degenerating fibers occurred and the different structures of the normal tissue were more easily identified. (3) At low concentrations of osmic acid and potassium chlorate, the contrast was diminished and artifacts produced by increasing the concentration of acetic acid or formalin or both. The new formula, based on the present results, consists of osmic acid, 0.5%, 11 ml.; potassium chlorate, 1%, 16 ml.; formalin (cone), 3 ml.; acetic acid, 10%, 3 ml.; and distilled water to make 100 ml. (All solutions are aqueous). Good staining after a long period of fixation in formalin, following degeneration of 8-80 days, was obtained and the cost of staining solution greatly reduced.     

Terminal degeneration in the mediodorsal cerebral cortex of the lizard Agama agama: Light and electron microscopy

The degeneration of axon terminals in the small-celled part of the mediodorsal cortex (sMDC) of the lizard Agama agama has been studied after lesions in the dorsal cortex at various survival periods. The Fink-Heimer stain was used to map and demonstrate terminal degeneration with the light and electron microscope. Electron microscopy was used to identify and describe degenerating boutons ultrastructurally. One sham-operated and three unoperated animals served as controls. Between 6 and 21 days postsurgically, degenerating terminals can be seen through 80% of the superficial plexiform layer, the zone adjacent to the cellular layer remaining free of degeneration. Swelling of dendrites in the outer part of the superficial plexiform layer and increased numbers of vacuolar invaginations, both present at short (24 hr–6 days; peak at 48–54 hr) survival periods, can be regarded as reaction to the surgical trauma. Degeneration of axon terminals takes three forms, all of the electron-dense type: gray boutons, degenerating bouton-dendritic spine complexes surrounded or engulfed by glia, and degeneration debris inside glial processes. Several forms of terminal degeneration occur concomitantly at any short (3–12 days) survival time. At longer survival times (15–21 days) only debris is present. From 6 days on, considerable numbers of degenerating structures are present, but the majority of degenerating boutons and debris are associated with reactive glia rather than with dendrites. From these observations it is concluded that in this lizard application of the combined degeneration-Golgi-EM technique would probably lead to little success. Electron microscopy of Fink-Heimer-stained sections suggests that degenerating bouton-dendritic spine complexes and degeneration debris accumulate silver particles, whereas gray boutons do not.     

Feulgen staining of rat liver fixed in different fixatives.

In the present study rat liver pieces fixed in 1) 10 per cent buffered neutral formalin, 2) 4 per cent glutaraldehyde, 3) Heidenhain's-Susa fixative and 4) Flemming's fluid, and following hydrolysis in 1-0 N HC1 at 60degreesC for varying time periods have been stained with the UV Feulgen procedure. The results of this study reveal that following hydrolysis for different time periods the tissue material fixed in formalin show the same staining pattern as those fixed in glutaraldehyde. The material fixed in Heidenhain's-Susa displays an intense Feulgen staining after two different times of hydrolysis, and that fixed in Flemming's fluid shows particular staining intensity for a prolonged time period thus indicating better preservation of DNA than in the materials fixed in the other three fixtatives.     

Preparation of Brain Slices for Macroscopic Study by the Copper Sulfate-Phenol-Ferrocyanide Technique

The technique of Mulligan (J. Anat., 65: 468-72, 1931) for preparing gross brain slices has been modified to include improvements in fixation, slicing and staining. The iron alum-tannic acid steps have been eliminated and potassium ferrocyanide substituted. Washing times have been reduced and a detailed routine for fixation and slicing developed. After postmortem removal, human brains were perfused with 40% formalin and kept suspended in 10% formalin for 2-4 wk. Serial slices, 4 mm thick, were cut with an electrically driven rotary-blade meat slicer, washed in running water for 12 hr, immersed in CuSO₄-phenol solution (0.5%: 5%) at 60 C for 6 min, washed again in running water for 5 min, and then treated with a 2% solution of potassium ferrocyanide until a red-brown color developed in the gray matter, usually within 30-60 sec. The slices were then washed again for 5 min and stored in 10% formalin. Brains of patients over 60 yr of age frequently stained poorly and were not used.     

Viability of meiotic prophase spermatocytes of rats is facilitated in primary culture of dispersed testicular cells on collagen gel by supplementing epinephrine or norepinephrine: Evidence that meiotic prophase spermatocytes complete meiotic divisions in vitro

Summary Dispersed testicular cells prepared from 14-d-old rats were cultured on type 1 collagen gels using a medium composed of a 1∶1 mixture of Ham’s F12 medium and Leibovitz’s L15 medium (F12-L15 medium) containing 10% (vol/vol) fetal bovine serum. The viability of the spermatogenic cells was facilitated by supplementing a rat adrenal extract into the medium. The effective substance(s) (the survival factor) was purified from acid extracts of adrenals by molecular sieve high performance liquid chromatography and identified as epinephrine and norepinephrine. Both epinephrine and norepinephrine promoted the survival of the spermatogenic cells with a half saturating dose of 10 ng/ml. The spermatogenic cells, which could be cultured for 2 wk on a collagen gel by supplementing with the survival factor (epinephrine or norepinephrine), were subjected to Giemsa staining and to DNA flow cytometry. The following results were obtained: a) The spermatogenic cells from 14-d-old rats did not contain spermiogenic cells (lc-cells). b) During a culture period of 2 to 7 d the ratio of meiotic prophase spermatocytes (4c-cells) to premeiotic cells (2c-cells) increased. On Day 7, more than 90% of the surviving cells were meiotic prophase spermatocytes. c) On Day 10, spermatids (lc-cells) appeared for the first time. The time of the first appearance of spermatids in the culture was consistent with that in vivo. These results suggest that both epinephrine and norepinephrine facilitated the viability of meiotic prophase spermatocytes and that a part of the meiotic prophase spermatocytes completed the meiotic divisions in the testicular cell culture.     

Controlled Differentiation of Cells and Connective Tissue Fibers in Silver Staining

Controlled silver staining of connective tissue fibers and sometimes of these fibers and cells simultaneously can be obtained. 1. Fix in 10% formalin. Embed in paraffin and cut sections as usual, but do not mount them on slides. Deparaffinize and hydrate through xylene, alcohols and distilled water and henceforth treat them the same as frozen sections. Real frozen sections can also be used. 2. Treat with a freshly prepared 1% solution of KMnO₄, usually 15-60 sec, sometimes up to 10 min. 3. Wash in distilled water, 5-10 sec. 4. Decolorize in 2% potassium metabisulfite, 10-20 sec. 5. Place in distilled water, 1 min. 6. Sensitize with 2% iron alum, 1 min. 7. Place in distilled water, 1 min. 8. Impregnate in Gomori's silver oxide solution, 2 min. 9. Wash in a 1.5% aqueous solution of pyridine, about 15 sec. 10. Reduce in a mixture containing 0.25% gelatin and 2% formalin 1 min. 11. Repeat steps 7 to 10 once or several times until the connective tissue fibers are completely stained. For cell staining (which may fail) proceed as follows: After the first insufficient staining of the connective tissue fibers, rinse in distilled water, dip for 1 sec in Gomori's solution and reduce immediately in gelatin-formalin without previous washing in pyridined water. This step can be repeated. 12. If the staining is too strong, decolorize as needed in 2% iron alum. 13. Toning in 0.2% gold chloride, 5 min or more, followed by fixation in 5% sodium thiosulfate, 1 min, is optional. Counterstain as desired. 14. Wash in tap water, dehydrate, clear in xylene and mount in balsam. The same technique applied to sections attached to slides gives good results but inferior to that obtained in paraffin sections processed in the loose, unmounted condition.     

Effects of prolonged water washing of tissue samples fixed in formalin on histological staining

The effects of prolonged water washing after fixation for 48 h in 10% (v/v) phosphate-buffered neutral formalin on the quality of representative histological staining methods were evaluated using samples of liver, kidney, spleen and thymus collected from three male Crl:CD(SD)(IGS) rats and one male beagle dog. Because door-to-door courier services in Japan prohibit handling formalin, our goal was to confirm that formalin fixed wet tissue samples could be stored in tap water rather than formalin during transportation of the samples without decreasing the quality of their staining or immunohistochemistry. Each tissue sample was allocated randomly to one of three groups: 12 min, 3 days and 7 days of washing in running tap water; samples then were routinely embedded in paraffin and sectioned. The sections were stained with hematoxylin and eosin, periodic acid-Schiff, azan, and the TdT-mediated dUTP-biotin nick end labeling (TUNEL) method. Immunohistochemical staining for Factor VIII, ED-1 and CD3 also was assessed. Prolonged water washing for up to 7 days did not affect the morphology or stainability by standard histological methods, or the intensity and frequency of positive reactions using the TUNEL method. Only immunohistochemical staining of Factor VIII was altered in both the rat and dog sections after 7 days of water washing. The intensity of positive reactions of Factor VIII immunohistochemistry after 7 days water washing was still strong enough to detect microscopically. Therefore, prolonged water washing for up to 7 days after formalin fixation does not have seriously detrimental effects on the quality and characteristics of paraffin sections stained by various methods, including immunohistochemistry.     

Development of a monoclonal antibody that specifically detects tissue inhibitor of metalloproteinase‐4 (TIMP‐4) in formalin‐fixed,paraffin‐embedded human tissues

Overexpression of the extracellular metalloproteinase inhibitor TIMP‐4 in estrogen receptor‐negative breast cancers was found recently to be associated with a poor prognosis for survival. To pursue exploration of the theranostic applications of TIMP‐4, specific antibodies with favorable properties for immunohistochemical use and other clinical assays are needed. Here we report the characterization of a monoclonal antibody (clone 9:4–7) specific for full‐length human TIMP‐4 with suitable qualities. The antibody was determined to be an IgG_2b immunoglobulin. In enzyme‐linked immunosorbent assay (ELISA) and immunoblotting assays, it did not exhibit any detectable crossreactivity with recombinant forms of the other human TIMPs 1, 2, and 3. In contrast, the antibody displayed high specificity and sensitivity for TIMP‐4 including in formalin‐fixed and paraffin‐embedded specimens of human breast specimens. An analysis of tissue microarrays of human cancer and corresponding normal tissues revealed specific staining patterns with excellent signal‐to‐noise ratios. This study documents TIMP‐4 monoclonal antibody clone 9:4–7 as an effective tool for preclinical and clinical investigations. J. Cell. Biochem. 110: 1255–1261, 2010. Published 2010 Wiley‐Liss, Inc.