Factors Affecting Triple Staining of Human Sperm

We have previously described a triple stain for evaluating normal acrosome reactions of human sperm. This procedure uses trypan blue to distinguish live and dead sperm, Bismarck brown to stain the sperm's postacrosomal region, and rose Bengal to stain the sperm's acrosome. We have recently found that batches of rose Bengal vary significantly in their ability to produce good staining of the acrosome in this procedure. This appears to be due to variations in the intrinsic pH of rose Bengal solutions and the presence of nondye contaminants in the stain. In this study, we have evaluated acrosomal staining using 6 batches of rose Bengal and report a method for achieving uniform staining quality with each batch. Solutions of rose Bengal (0.8%) are made up in 0.1 M Tris HC1 (pH 2.3) buffer and adjusted to pH 5.3 if necessary. For most batches of rose Bengal this promotes precipitation of some of the dye and an unidentified contaminating crystal. The precipitate is removed by centrifugation, and the supernatants have been found to give good to excellent staining of the acrosomes for all batches tested. Solutions of both rose Bengal and Bismarck brown are stable for at least 5 days but their pH values should be monitored daily and adjusted to 5.3 and 1.8 respectively if drifting occurs. We have also observed some variation in the intensity of rose Bengal staining of the acrosome from donor to donor and recommend that staining times in rose Bengal be adjusted for each donor.     

Factors affecting triple staining of human sperm

We have previously described a triple stain for evaluating normal acrosome reactions of human sperm. This procedure uses trypan blue to distinguish live and dead sperm, Bismarck brown to stain the sperm's postacrosomal region, and rose Bengal to stain the sperm's acrosome. We have recently found that batches of rose Bengal vary significantly in their ability to produce good staining of the acrosome in this procedure. This appears to be due to variations in the intrinsic pH of rose Bengal solutions and the presence of nondye contaminants in the stain. In this study, we have evaluated acrosomal staining using 6 batches of rose Bengal and report a method for achieving uniform staining quality with each batch. Solutions of rose Bengal (0.8%) are made up in 0.1 M Tris HCl (pH 2.3) buffer and adjusted to pH 5.3 if necessary. For most batches of rose Bengal this promotes precipitation of some of the dye and an unidentified contaminating crystal. The precipitate is removed by centrifugation, and the supernatants have been found to give good to excellent staining of the acrosomes for all batches tested. Solutions of both rose Bengal and Bismarck brown are stable for at least 5 days but their pH values should be monitored daily and adjusted to 5.3 and 1.8 respectively if drifting occurs. We have also observed some variation in the intensity of rose Bengal staining of the acrosome from donor to donor and recommend that staining times in rose Bengal be adjusted for each donor.     

Staining procedure to detect viability and the true acrosome reaction in spermatozoa of various species

A simple dual stain procedure (DS) for simultaneously determining sperm viability and acrosomal status is described. The DS includes the use of the vital stain trypan blue to detect live and dead spermatozoa and Giemsa to detect the presence or absence of an acrosome. For staining, spermatozoa are washed, incubated with trypan blue, washed, dried onto slides, and subjected to Giemsa. Dead spermatozoa stain blue in the postacrosomal region while live spermatozoa remain unstained. The acrosome stains light purple–dark pink while acrosome-free sperm remain unstained. This staining pattern enables differentiation of spermatozoa which have undergone a true acrosome reaction (TAR) from those which have undergone a false acrosome reaction (FAR). Incubation of bull, boar, ram, and stallion spermatozoa for 60 minutes at 37°C in the presence of calcium ionophore A23187 increased the proportion of spermatozoa undergoing a TAR in all species except the stallion. Incubation of bull spermatozoa for up to 24 hours at 37°C resulted in a decrease over time in the percentage of live acrosome-intact spermatozoa and a simultaneous increase in the percentage of spermatozoa categorized as having undergone a TAR and FAR. The DS could be a useful technique in evaluating sperm viability and acrosomal status in fertilization and clinical studies.     

Evaluation of sperm acrosome reaction in the Asiatic elephant

This study focuses on the effect of chemicals on acrosome reaction in elephant spermatozoa. Semen was collected at the Washington Park Zoo in Portland, Oregon, from an 11-yr-old Asian elephant by artificial vagina (7 ejaculates) and transported to Mahidol University in Bangkok in extender at 4 to 5 degrees C within 24 to 28 h. A total of 500 x 10(6) sperm/mL was used for the control and for each of the 4 treatment groups: 1) cAMP (0.1 mM); 2) caffeine (0.1 mM); 3) Penicillamine hypotaurine and epinephine, PHE (penicillamine 2 mM, hypotaurine 1 mM, epinephine 1 mM); and 4) heparin (10 microg/mL) at 39 degrees C for 2 h. Aliquots were removed and the sperm viability, abnormal morphology, and acrosome status were evaluated by triple stain technique. Transmission electron microscopy (TEM) was used to observe changes of the sperm head membrane in all treatment groups. Trypan blue reliably stained dead spermatozoa, while rose Bengal stained only the spermatozoa with intact acrosomes. The concentration of dead sperm cells was similar in the 4 groups. The percentages of live acrosome-reacted spermatozoa in the control and in groups treated with caffeine, PHE, cAMP and heparin were 19.5 +/- 4.3, 38.1 +/- 4.0, 34.8 +/- 3.7, 29.8 +/- 0.8 and 28.0 +/- 4.2, respectively. The acrosome reaction rate was higher in the treatment groups than in the control (P<0.05). Caffeine and PHE caused significantly higher acrosome reaction of the sperm head than cAMP or heparin (P<0.05). The electron micrographs showed that the acrosome reaction occurred by the presence of apical vesiculation. The results indicated that 1) the triple stain technique allowed for evaluation of both viability and acrosome reaction simultaneously in elephant spermatozoa,2) acrosome reaction occurred at a high rate in all 3 treatment groups. 3) the effects of caffeine and PHE were significantly higher (P<0.05) than of cAMP and heparin, and 4) the data obtained from the triple stain technique corresponded to those from TEM.     

Simultaneous evaluation of viability and acrosome integrity of mouse spermatozoa using light microscopy

Determination of the percentage of live cells with intact acrosomes and no morphologic aberrations could be a practical index of semen quality. We applied viability and acrosome staining techniques, originally described for bull, boar and rabbit sperm, to mouse spermatozoa. The viability stain was either trypan blue or Congo red. The stain was precipitated by neutral red in the fixative. The acrosome was stained by Giemsa. Sperm morphology, including cytoplasmic droplets, could be evaluated as well. The staining method described here is a useful routine tool for simultaneous evaluation of the plasma membrane integrity of different sperm subdomains, the status of the acrosome, and cellular morphology.     

Observations on the acrosome reaction of human sperm in vitro

Human sperm were incubated in vitro in serum or the defined medium TMPA and were periodically assessed for acrosome reactions using two new methods of assay. The first method, FITC-RCA labeling, was previously shown to be valid for estimating the percentage of normal acrosome reactions of human sperm. The second method, a triple staining technique, is shown in this study to give results comparable to those obtained with FITC-RCA labeling. The percentage of acrosome-reacted sperm was determined at 0, 2.5, 5, and 7 hr of incubation. In both media, some sperm had reacted by 2.5 hr; a maximum percentage of reactions occurred between 5 and 7 hr. The maximum percentage never exceeded 20–25%, which represents only one-third of the live sperm, ie, those potentially able to undergo normal acrosome reactions. It will be important in future studies to determine if this low-peak percentage is due to the fact that: (1) Commonly used culture media are suboptimal or (2) only about 25% of the sperm in a human ejaculate are capable of undergoing normal acrosome reactions.     

Acrosome reaction induced by immunoaggregation of a proteinase inhibitor bound to the murine sperm head.

ZP3, a glycoprotein of the murine zona pellucida, functions both to bind acrosome intact sperm and to induce the acrosome reaction. Solubilized whole zonae as well as purified ZP3 are able to induce acrosome reactions in capacitated sperm. Pronase digests of whole zonae yield glycopeptides that bind to sperm but are unable to induce acrosome reactions. However, immunoaggregation of these glycopeptides results in the exocytosis of the acrosome in the majority of treated sperm. The data suggest that ZP3 triggers the acrosome reaction by the aggregation of ZP3 binding sites on the sperm head. If aggregation of ZP3 binding sites is important in the induction of the acrosome reaction, then it may be possible to induce the acrosome reaction in the absence of zona by immunoaggregation of the sites. This presentation deals with the immunoaggregation of a proteinase inhibitor of seminal vesicle origin (SVI) that binds to a site on the sperm head known to participate in zona binding. We show that capacitated murine sperm, pretreated with the SVI, will acrosome react, as determined by Coomassie brilliant blue staining, when incubated with rabbit antiinhibitor antiserum (anti-SVI). The percentage of SVI-treated sperm displaying an acrosome reaction is dependent on the concentration of the immune serum. Sperm stain positive for intact acrosomes when anti-SVI Fab fragments or normal rabbit serum is substituted for the immune serum. However, when capacitated sperm, treated with both SVI and anti-SVI Fab fragments, are incubated with goat antirabbit IgG, the majority of sperm acrosome react. The data suggest that the aggregation of SVI bound to the sperm surface, in the absence of zona glycoproteins, is sufficient to induce the acrosome reaction.     

A new procedure for rapidly scoring acrosome reactions of human sperm

Because the acrosome of human sperm is too small to be directly visualized by phase-contrast microscopy, acrosome reactions (that is loss of the acrosome) are generally not evaluated in studies of human sperm capacitation and fertilization. Nevertheless, it would be useful in such studies to have a technique for easily identifying and quantitating acrosome-reacted sperm. In this paper, we describe a method for labeling the human sperm acrosome with fluorescein-conjugated Ricinus communis agglutinin-60 (FITC-RCA); we show that in sperm without acrosomal caps, FITC-RCA labeling occurs either not at all or only in the equatorial segment of the acrosome. To determine if the absence of FITC-RCA labeling in the acrosomal cap region gives a reliable estimate of acrosome reactions, washed sperm or sperm incubated in a capacitating medium (BWW) were divided into two groups, which were then fixed for FITC-RCA labeling or transmission electron microscopy. Counts of acrosome reactions made by each method were similar, and we observed an increase in the percentage of reactions following incubation in BWW. We conclude that the FITC-TCA labeling technique is a reliable method for accurately scoring the percentage of acrosome-reacted human sperm.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2–4 h Giemsa staining at 25–40° C is recommended for stallion semen.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2-4 h Giemsa staining at 25-40° C is recommended for stallion semen.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa.

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2-4 h Giemsa staining at 25-40 degrees C is recommended for stallion semen.     

Influence of thawing method on motility, plasma membrane integrity and morphology of frozen-thawed stallion spermatozoa

Different thawing methods are used for stallion semen, however, it is unclear which method is the optimal one. To determine if the thawing temperature has an effect on semen quality, we compared 2 thawing temperatures, 75 degrees C and 37 degrees C. The following parameters were used to measure sperm quality: sperm motility, sperm viability, plasma membrane integrity and sperm morphology. Twenty-three ejaculates from 10 Dutch Warmblood stallions were thawed either at 37 degrees C for 30 sec or at 75 degrees C for 7 sec. Sperm motility was evaluated by a Hamilton Thorn Motility Analyser. Plasma membrane integrity and sperm viability were evaluated by using a live/dead fluorescein stain containing a calcein AM probe and ethidium homodimer-1 probe. The eosinaniline blue staining method was used to evaluate the percentage of live and dead cells, as well as sperm morphology. There was no significant difference (P = 0.84) between sperm motility after thawing at 37 degrees C and 75 degrees C. There was also no significant difference (P = 0.053) between the percentage of live spermatozoa using the calcein AM/ethidium homodimer stain after thawing at 37 degrees C and 75 degrees C. There was, however, a significant difference (P = 0.032) between the percentage of live spermatozoa using the eosin-aniline blue stain after thawing at 37 degrees C compared with that at 75 degrees C. In conclusion, our laboratory results indicated that stud farms using frozen semen should thaw the straws at 37 degrees C instead of 75 degrees C. The lower temperature is easier to work with, as thawing at the higher temperature requires special equipment and has to be timed very carefully to avoid damage to the spermatozoa.     

Viability and Acrosome Staining of Bull, Boar and Rabbit Spermatozoa

A practical and reliable staining procedure was developed to distinguish the viability and acrosomal status of bull, boar and rabbit spermatozoa. The first stain with trypan blue or Congo red is rapid and avoids artifacts. This stain is precipitated by neutral red during the 2 min required for fixation. The precipitate gives a high contrast black color, resistant to the subsequent rinsings and persists during the time required for staining the acrosome with Giemsa. Ten classes of spermatozoa are distinguished (live or dead with intact acrosomes, loose acrosomes, damaged acrosomes, no acrosome, or with no acrosome and no postacrosomal ring). The intact acrosomes are purple, the loose acrosomes are dark lavender and the damaged acrosomes are pale lavender. The anterior part of the head of live spermatozoa with no acrosome is white or light pink and the same area of dead spermatozoa is white or pale gray. The postacrosomal ring is red. The postacrosomal area of the head of live spermatozoa is white or light pink and the same part of dead spermatozoa is black, dark violet or gray. The procedure did not give satisfactory results for stallion spermatozoa.     

A Simple Staining Procedure for Detecting the true Acrosome Reaction in Buffalo (Bubalus bubalis) Spermatozoa

A simple dual staining procedure for detecting the true acrosome reaction in dried smears of buffalo spermatozoa is described. Trypan blue is used first to differentiate live from dead spermatozoa and the dried smears which have been prepared are stained with Giemsa for acrosome evaluation. Four categories of spermatozoa were recognized: A) live, intact acrosome (acrosome pink, postnuclear cap clear); B) dead, intact acrosome (acrosome pink, postnuclear cap blue); C) live, detached acrosome (acrosome clear, postnuclear cap clear); and D) dead, detached acrosome (acrosome clear, postnuclear cap blue). The procedure is simple, rapid and convenient for assessing true acrosome reaction in buffalo spermatozoa. Simultaneous assessment of sperm viability and its acrosomal status in dried smears makes this procedure attractive because the true acrosome reaction can be studied thoroughly at a later state after the incubation period.     

SpermBlue®: A new universal stain for human and animal sperm which is also amenable to automated sperm morphology analysis

Abstract

Our study was aimed at exploring a simple procedure to stain differentially the acrosome, head, midpiece, and flagellum of human and animal sperm. A further prerequisite was that sperm morphology of the stained samples could be analyzed using automated sperm morphology analysis (ASMA). We developed a new staining process using SpermBlue® fixative and SpermBlue® stain, which are iso-osmotic in relation to semen. The entire fixation and staining processes requires only 25 min. Three main steps are required. First, a routine sperm smear is made by either using semen or sperm in a diluting medium. The smear is allowed to air dry at room temperature. Second, the smear is fixed for 10 min by either placing the slide with the dried smear in a staining tray containing SpermBlue® fixative or by adding 1 ml SpermBlue® fixative to the slide. Third, the fixed smear is stained for 15 min by either immersing the slide in a staining tray containing SpermBlue® stain or adding four drops of SpermBlue® stain to the fixed smear. The stained slide is dipped gently in distilled water followed by air drying and mounting in DPX® or an equivalent medium. The method is simple and suitable for field conditions. Sperm of human, three monkey species, horse, boar, bull, ram, mouse, rat, domestic chicken, fish, and invertebrate species were stained successfully using the SpermBlue® staining process. SpermBlue® stains human and animal sperm different hues or intensities of blue. It is possible to distinguish clearly the acrosome, sperm head, midpiece, principal piece of the tail, and even the short end piece. The Sperm Class Analyzer® ASMA system was used successfully to quantify sperm head and midpiece measurements automatically at either 600 × or 1000 × magnification for most of the species studied.     

伊红、台盼蓝检测河蟹精子存活率的比较

对台盼蓝和伊红染色法检测河蟹(Eriocheir sinensis)精子存活率的方法进行了评价研究。结果表明,两种染色法死、活精子分别呈现出明显不同的染色特征:活精子无色透明,顶体中央凸起呈圆锥状,光镜下辐射臂及细胞边界清晰;死亡精子顶体着色,且中央有一染色较深的圆斑,核杯染色不明显,细胞体积变大,边界模糊。通过不同染色时间和不同染料浓度的比较发现,两种染色法最适染液浓度分别是0·25%的伊红和0·5%的台盼蓝,染色时间均以15min为佳。在此基础上,将新鲜精子和60℃水浴处理致死精子以不同的体积比混合,配成含致死精子比例为10%～90%的9个梯度样品,用伊红和台盼蓝分别测定各样品精子死亡率,并进行相关性分析。结果发现,各样品实测精子死亡率均略高于样品的理论死亡率,同时两种染色法实测值与样品理论值呈显著正相关(P<0·05),两种染色法之间亦呈显著正相关(P<0·05)。上述结果表明,伊红和台盼蓝可用于河蟹精子的活体染色,且两种染色法在对河蟹精子染色中具有一定的稳定性和可比性。     

The effect of heparin, caffeine and calcium ionophore A23187 on in vitro induction of the acrosome reaction in frozen-thawed bovine and caprine spermatozoa

The effect of heparin (5 IU), caffeine (5 mM) and calcium-ionophore A23187 (0.1 mM) on motility and in vitro induction of the acrosome reaction in glass wool filtered frozen-thawed bull and goat semen was studied. The motile spermatozoa fraction was obtained after glass wool filtration of frozen-thawed semen. The seminal plasma was removed from filtered semen by centrifugation, and the sperm pellet was resuspended in Sperm-TALP medium. Samples of treated and untreated control semen of both species were incubated at 37 degrees C. At 1, 15 and 30 min of incubation the proportions of progressively motile and acrosome-reacted spermatozoa were assessed. Trypan blue and Giemsa stain was used to differentiate live and dead spermatozoa having undergone acrosome reaction. Glass wool filtration enhanced the proportion of motile spermatozoa from 43% to 62% in the bovine and from 41% to 60% in the caprine. Whereas the effect of incubation with caffeine, heparin and calcium-ionophore on spermatozoan motility was negligible, the treatment of semen with calcium-ionophore resulted in a significantly improved percentage of live spermatozoa with true acrosome reaction at all stages of incubation, both in the bovine and the caprine.     

Use of fluorescent probes to assess membrane integrity in mammalian spermatozoa.

Carboxyfluorescein diacetate and propidium iodide were used as fluorescent stains to assess membrane integrity in sperm populations from ram and boar. The living spermatozoa were immobilized with low concentrations of formaldehyde so that individual stained cells could be observed in a suspension with the aid of a fluorescence microscope. Intracellular esterases liberated impermeant-free carboxyfluorescein from the permeant carboxyfluorescein diacetate and caused the product to accumulate and fluoresce green within the acrosome and the mitochondria as well as within the cytoplasm. Most of the spermatozoa (the intact ones) accumulated carboxyfluorescein in all compartments; however, a few cells (those with damaged plasma membranes) accumulated the stain only in the acrosome and/or the mitochondria, while others (all of whose membranes were damaged) remained entirely unstained. The impermeant propidium iodide did not stain any of the (intact) spermatozoa that accumulated carboxyfluorescein throughout their length, but stained all the others (the heads fluoresced red). The technique appeared to provide more reliable estimations of the percentage of functional cells than did motility estimations or assessments of acrosomal integrity (presence of normal apical ridge). The technique also demonstrated the sensitivity of the sperm plasma membrane to cold shock: virtually all cells rapidly became permeable to the stains after such stress. Assessments of boar sperm samples during preparative incubation for in-vitro fertilization indicated a considerable increase in the percentage of cells with damaged plasma membranes as incubation proceeded, in advance of the increase in the percentage of cells with discharged acrosomes.     

Induction of acrosome reactions by the human zona pellucida

We have used two approaches to test the ability of the human zona pellucida to induce acrosome reactions in human sperm. First, nonviable human oocytes were incubated for 1 min in a suspension of capacitated sperm (of which fewer than 5% were acrosome-reacted) to allow binding of about 200 sperm per oocyte. Some of the oocytes were fixed immediately, and the remainder were fixed after a further 1-h incubation without free-swimming sperm. As determined by light microscopy, sperm on the zona were only 3 +/- 2% (avg. +/- SD) acrosome-reacted at 1 min, and the incidence increased to 46 +/- 15% during the next hour. Electron microscopy confirmed that most sperm on the zona at 1 min were acrosome-intact. A few sperm were in an early stage of the acrosome reaction. Acrosome reactions occurring on the zona during the subsequent hour appeared to be morphologically normal. Second, treatment of sperm in suspension with acid-disaggregated zonae (2 to 4 zonae/microliter) increased the incidence of acrosome-reacted sperm from 3 +/- 1% to 24 +/- 4%. We conclude that the human zona pellucida, or material intimately associated with it, can induce acrosome reactions in human sperm.     

Plant-Virus Differentiation by Trypan-Blue Reactions within Infected Tissue

Trypan blue has proved effective for demonstrating the presence of certain plant viruses within infected tissues. The amorphous and crystalline inclusions which constitute cytological evidence of viruses stain proportionately. The effects produced by different viruses react differently to the stain and those inclusions which do not absorb trypan blue tend to stain with phloxine. This selective staining is the basis for using trypan blue singly and in combination with phloxine as standardized procedures for demonstrating and differentiating cytological evidence of plant viruses. These tests are very rapid and are especially applicable to temporary mounts of living tissue but permanent mounts can be made from material fixed in formalin.